Functional validation of a packet management unit

ABSTRACT

A validation system is disclosed for validating function of a packet-management unit operationally coupled through a system interface to a processing unit of a processor system. The validation system comprises a user interface for creating an inputting test parameters and test code into the system, a test generator coupled to the user interface, the test generator for generating input packet activity in the form of a packet stream, a model coupled to the test generator for emulating separate and integrated function of the packet management unit, the system interface, and a stream-processing unit and an evaluation software for checking and validating or not validating results. The system validation function relies, in a preferred embodiment, on comparing output results with criteria of the selected test code resulting in an indication of pass or failure of the test. In a preferred embodiment, the system also notifies to cause of failure.

CROSS-REFERENCE TO RELATED DOCUMENTS

The present invention is a continuation in part (CIP) to a U.S. patent application Ser. No. 09/737,375 entitled “Queuing System for Processors in Packet Routing Operations” and filed on Dec. 14, 2000, which is included herein by reference. In addition, Ser. No. 09/737,375 claims priority benefit under 35 U.S.C. 119 (e) of Provisional Patent Application Ser. No. 60/181,364 filed on Feb. 8, 2000, and incorporates all disclosure of the prior application by reference. The present application is also a continuation in part of application Ser. No. 09/608,750, filed on Jun. 30, 2000 and Ser. No 09/602,279, filed Jun. 23, 2000 and incorporates all of their disclosure by reference.

FIELD OF THE INVENTION

The present invention is in the field of digital processing and pertains to apparatus and methods for processing packets in routers for packet networks, and more particularly to apparatus and methods for validating packet management hardware functions and design integrity in process.

BACKGROUND OF THE INVENTION

The well-known Internet network is a notoriously well-known publicly-accessible communication network at the time of filing the present patent application, and arguably the most robust information and communication source ever made available. The Internet is used as a prime example in the present application of a data-packet-network which will benefit from the apparatus and methods taught in the present patent application, but is just one such network, following a particular standardized protocol. As is also very well known, the Internet (and related networks) are always a work in progress. That is, many researchers and developers are competing at all times to provide new and better apparatus and methods, including software, for enhancing the operation of such networks.

In general the most sought-after improvements in data packet networks are those that provide higher speed in routing (more packets per unit time) and better reliability and fidelity in messaging. What is generally needed are router apparatus and methods increasing the rates at which packets may be processed in a router.

As is well-known in the art, packet routers are computerized machines wherein data packets are received at any one or more of typically multiple ports, processed in some fashion, and sent out at the same or other ports of the router to continue on to downstream destinations. As an example of such computerized operations, keeping in mind that the Internet is a vast interconnected network of individual routers, individual routers have to keep track of which external routers to which they are connected by communication ports, and of which of alternate routes through the network are the best routes for incoming packets. Individual routers must also accomplish flow accounting, with a flow generally meaning a stream of packets with a common source and end destination. A general desire is that individual flows follow a common path. The skilled artisan will be aware of many such requirements for computerized processing.

Typically a router in the Internet network will have one or more Central Processing Units (CPUs) as dedicated microprocessors for accomplishing the many computing tasks required. In the current art at the time of the present application, these are single-streaming processors; that is, each processor is capable of processing a single stream of instructions. In some cases developers are applying multiprocessor technology to such routing operations. The present inventors have been involved for some time in development of dynamic multi-streaming (DMS) processors, which processors are capable of simultaneously processing multiple instruction streams. One preferred application for such processors is in the processing of packets in packet networks like the Internet.

In the provisional patent application listed in the Cross-Reference to Related Documents above there are descriptions and drawings for a preferred architecture for DMS application to packet processing. One of the functional areas in that architecture is a packet management unit (PMU) comprising hardware and circuitry for processing data packets.

As described with reference to Ser. No. 09/737,375 in FIG. 1 above the PMU is the part of the processor, known as the XCaliber processor in some instances, that offloads the streaming processor unit (SPU) from performing costly packet header accesses and packet sorting and management tasks, which might otherwise seriously degrade performance of the overall processor.

Packet management functions of the PMU include managing on-chip local packet memory (LPM) for packet storage, uploading packet header information from incoming packets into different contexts registers of the XCaliber processor, and maintaining packet identifiers of the packets currently in process in the XCaliber processor.

There are at least two known means of functionally verifying a PMU. One of these involves using well-known verification techniques, but these are suitable typically for only small designs, and the formal verification technology is not advanced enough. Another is to compare performance of a PMU of unknown quality with an already-verified model. A model can be a completed and functional chip, a model made of pieces of other chips, or a model made of part hardware and part software. A problem here is that, for PMUs of the sort to be tested and verified, there is no verified model, and a first model needs to be verified somehow.

Therefore, what is clearly needed is a reliable and cost-effective method and apparatus for validating packet-managing (PMU) functions in a packet processor, in the absence of an existing and verified model. The present invention teaches apparatus and methods to fill this need.

SUMMARY OF THE INVENTION

In a preferred embodiment of the present invention, a validation system is provided for validating function of a packet-management unit (PMU) operationally coupled through a system interface to a processing unit of a packet processor. The validation system comprises a user interface for creating and inputting test parameters and test code into the system, a test generator coupled to the user interface, the test generator for generating input packet activity in the form of a packet stream, a model coupled to the test generator for emulating separate and integrated function of the packet management unit, the system interface, and the stream-processing unit, and an evaluation software for checking and validating or not validating results.

A user inputs criteria and a selected test code into the test generator whereupon the test generator generates an input packet stream and an associated workload for input into the model and whereupon the model processes the packets and generates output activity that is compared to criteria of the selected test code resulting in an indication of pass or failure of the test.

In one aspect, the user interface is a computer. Also, in one aspect, the model is a software model running on a processor-based machine. In a preferred aspect, the test code comprises a plurality of values representing different combinations of possible test variables associated with treating data packets in process. In a preferred aspect, the model emulates integrated function of a data packet router having hardware and software controlled memory.

In a preferred aspect, the test variables include the possibility of packet modification by software, packet insertion by software, packet dropping by hardware or software, and packet reordering by software. In this aspect, each of the test variables are configured to be constrained or not in any specific combination, a specific combination thereof equating to one selectable test code value of a plurality of configured values.

In some cases the test is terminated after a specific number of cycles input before the test is performed; while in other a sweep packet of low processing priority is input after the test packets, and the test is determined to be complete, and is terminated, when the sweep packet is output by the model under test; and in still other cases the test is determined to be complete, and is terminated, when the number of packets output by the model equals the number of test packets input, plus any packets generated by the model.

In preferred embodiments a packet identifier is associated with every test packet, and the workload to be executed when the packet is activated is known by referring to the identifier.

In another aspect of the present invention, a method is provided for validating function of a packet-management unit (PMU) operationally coupled through a system interface to a processing unit of a packet processor. The method comprises the steps of, (a) specifying a list of test parameters and selecting test code for use in a validation test run, (b) inputting the specified and selected data into a test generator for generating a test; (c) converting, within the generator, the specified and selected data values into input vectors representing a data packet stream and associated workload, (d) inputting the generated data packet stream and associated workload into a model, the model simulating singular and integrated functions of the packet-management unit, the system interface, and the stream processing unit, (e) outputting from the model, an output activity representing the input data packet stream after processing and (f) examining the output activity according to input parameters and criteria of the selected test code to determine if the concluded test has passed or failed.

In a preferred embodiment, step (a) is performed by a user operating a computer. In one aspect of the method in step (d), the model is a software model running on a processor-based machine. In preferred aspects of the method in step (a), the test code comprises a plurality of values representing different combinations of possible test variables associated with treating data packets in process. In one aspect of the method in step (d), the model emulates integrated function of a data packet router having hardware and software controlled memory.

In a preferred aspect of the method in step (a) the test variables include the possibility of packet modification by software, packet insertion by software, packet dropping by hardware or software, and packet reordering by software. In this aspect, each of the test variables are configured to be constrained or not in any specific combination, a specific combination thereof equating to one selectable test code value of a plurality of configured values. In one aspect of the method in step (b), the specified data comprises determined value ranges assigned to a plurality of pre-determined characteristics of packet processing function. In another aspect of the method in step (d) inputting the generated data packet stream is an automated process. In alternative aspect of the method, a step (g) is added in case of failure at step (f) wherein notification is sent back to the user containing an explanation of the cause of failure.

In some cases of the method there is an additional step to determine a test is complete wherein the test is terminated after a specific number of cycles input before the test is performed; and in other cases an additional step determines a test is complete by inserting after the test packets a sweep packet of low processing priority, and determining the test to be complete when the sweep packet is output by the model under test; and in still other cases an additional step to determine a test is when the number of packets output by the model equals the number of test packets input, plus any packets generated by the model.

In some embodiments of the method there are steps for associating a packet identifier with every test packet, and determining the workload to be executed when the packet is activated by referring to the identifier.

Now, for the first time, a reliable and cost-effective method and apparatus is provided for validating PMU function in a packet processor. A method such as this is used to validate PMU functionality under simulation and to accurately troubleshoot any design flaws or performance issues before field implementation.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a simplified block diagram showing relationship of functional areas of a DMS processor in a preferred embodiment of the present invention.

FIG. 2 is a block diagram of the DMS processor of FIG. 1 showing additional detail.

FIG. 3 is a block diagram illustrating uploading of data into the LPM or EPM in an embodiment of the invention.

FIG. 4 a is a diagram illustrating determination and allocation for data uploading in an embodiment of the invention.

FIG. 4 b is a diagram showing the state that needs to be maintained for each of the four 64 KB blocks.

FIGS. 5 a and 5 b illustrate an example of how atomic pages are allocated in an embodiment of the present invention.

FIGS. 6 a and 6 b illustrate how memory space is efficiently utilized in an embodiment of the invention.

FIG. 7 is a top-level schematic of the blocks of the XCaliber PMU unit involved in the downloading of a packet.

FIG. 8 is a diagram illustrating the phenomenon of packet growth and shrink.

FIG. 9 is a block diagram showing high-level communication between the QS and other blocks in the PMU and SPU in an embodiment of the present invention.

FIG. 10 is a table illustrating six different modes in an embodiment of the invention into which the QS can be configured.

FIG. 11 is a diagram illustrating generic architecture of the QS of FIGS. 2 and 7 in an embodiment of the present invention.

FIG. 12 is a table indicating coding of the outbound DeviceId field in an embodiment of the invention.

FIG. 13 is a table illustrating priority mapping for RTU transfers in an embodiment of the invention.

FIG. 14 is a table showing allowed combinations of Active, Completed, and Probed bits for a valid packet in an embodiment of the invention.

FIG. 15 is a Pattern Matching Table in an embodiment of the present invention.

FIG. 16 illustrates the format of a mask in an embodiment of the invention.

FIG. 17 shows an example of a pre-load operation using the mask in FIG. 16.

FIG. 18 illustrates shows the PMU Configuration Space in an embodiment of the present invention.

FIGS. 19 a, 19 b and 19 c are a table of Configuration register Mapping.

FIG. 20 is an illustration of a PreloadMaskNumber configuration register.

FIG. 21 illustrates a PatternMatchingTable in a preferred embodiment of the present invention.

FIG. 22 illustrates a VirtualPageEnable configuration register in an embodiment of the invention.

FIG. 23 illustrates a ContextSpecificPatternMatchingMask configuration register in an embodiment of the invention.

FIG. 24 illustrates the MaxActivePackets configuration register in an embodiment of the present invention.

FIG. 25 illustrates the TimeCounter configuration register in an embodiment of the present invention.

FIG. 26 illustrates the StatusRegister configuration register in an embodiment of the invention.

FIG. 27 is a schematic of a Command Unit and command queues in an embodiment of the present invention.

FIG. 28 is a table showing the format of command inserted in command queues in an embodiment of the present invention.

FIG. 29 is a table showing the format for responses that different blocks generate back to the CU in an embodiment of the invention.

FIG. 30 shows a performance counter interface between the PMU and the SIU in an embodiment of the invention.

FIG. 31 shows a possible implementation of internal interfaces among the different units in the PMU in an embodiment of the present invention.

FIG. 32 is a diagram of a BypassHooks configuration register in an embodiment of the invention.

FIG. 33 is a diagram of an InternalStateWrite configuration register in an embodiment of the invention.

FIGS. 34-39 comprise a table listing events related to performance counters in an embodiment of the invention.

FIG. 40 is a table illustrating the different bypass hooks implemented in the PMU in an embodiment of the invention.

FIG. 41 is a table relating architecture and hardware blocks in an embodiment of the present invention.

FIGS. 42-45 comprise a table showing SPU-PMU Interface in an embodiment of the invention.

FIGS. 46-49 comprise a table showing SIU-PMU Interface in an embodiment of the invention.

FIG. 50 is a diagram of a unit configuration of a multi-streaming processor according to an embodiment of the present invention.

FIG. 51 is a diagram of valid ordering of flows, according to an embodiment of the present invention.

FIG. 52 is a diagram of the PMU validation environment according to an embodiment of the present invention.

FIG. 53 is a flow diagram illustrating an automated validation test process according to an embodiment of the present invention.

FIG. 54 is a table illustrating generated test codes according to an embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

In the provisional patent application Ser. No. 60/181,364 referenced above there is disclosure as to the architecture of a DMS processor, termed by the inventors the XCaliber processor, which is dedicated to packet processing in packet networks. Two extensive diagrams are provided in the referenced disclosure, one, labeled NIO Block Diagram, shows the overall architecture of the XCaliber processor, with input and output ports to and from a packet-handling ASIC, and the other illustrates numerous aspects of the Generic Queue shown in the NIO diagram. The NIO system in the priority document equates to the Packet Management Unit (PMU) in the present specification. It is to the several aspects of the generic queue that the present application is directed.

FIG. 1 is a simplified block diagram of an XCaliber DMS processor 101 with a higher-level subdivision of functional units than that shown in the NIO diagram of the priority document. In FIG. 1 XCaliber DMS processor 101 is shown as organized into three functional areas. An outside System Interface Unit (SIU) area 107 provides communication with outside devices, that is, external to the XCaliber processor, typically for receiving and sending packets. Inside, processor 1011 is divided into two broad functional units, a Packet Management Unit (PMU) 103, equating to the NIO system in the priority document mentioned above, and a Stream Processor Unit (SPU) 107. The functions of the PMU include accounting for and managing all packets received and processed. The SPU is responsible for all computational tasks.

The PMU is a part of the XCaliber processor that offloads the SPU from performing costly packet header accesses and packet sorting and management tasks, which would otherwise seriously degrade performance of the overall processor.

Packet management is achieved by (a) Managing on-chip memory allocated for packet storage, (b) Uploading, in the background, packet header information from incoming packets into different contexts (context registers, described further below) of the XCaliber processor, (c) Maintaining, in a flexible queuing system, packet identifiers of the packets currently in process in the XCaliber.

The described packet management and accounting tasks performed by the PMU are performed in parallel with processing of packets by the SPU core. To implement this functionality, the PMU has a set of hardware structures to buffer packets incoming from the network, provide them to the SPU core and, if needed, send them out to the network when the processing is completed. The PMU features a high degree of programmability of several of its functions, such as configuration of its internal packet memory storage and a queuing system, which is a focus of the present patent application.

FIG. 2 is a block diagram of the XCaliber processor of FIG. 1 showing additional detail. SIU 107 and SPU 105 are shown in FIG. 2 as single blocks with the same element numbers used in FIG. 1. The PMU is shown in considerably expanded detail, however, with communication lines shown between elements.

In FIG. 2 there is shown a Network/Switching Fabric Interface 203 which is in some cases an Application Specific Integrated Circuit (ASIC) dedicated for interfacing directly to a network, such as the Internet for example, or to switching fabric in a packet router, for example, receiving and transmitting packets, and transacting the packets with the XCaliber processor. In this particular instance there are two in ports and two out ports communicating with processor 201. Network in and out interface circuitry 205 and 215 handle packet traffic onto and off the processor, and these two interfaces are properly a part of SIU 107, although they are shown separately in FIG. 2 for convenience.

Also at the network interface within the PMU there are, in processor 201, input and output buffers 207 and 217 which serve to buffer the flow of packets into and out of processor 201.

Referring again to FIG. 1, there is shown a Packet Management Unit (PMU) 103, which has been described as a unit that offloads the requirement for packet management and accounting from the Stream Processing Unit. This is in particular the unit that has been expanded in FIG. 2, and consists substantially of Input Buffer (IB) 207, Output Buffer (OB) 217, Paging Memory Management Unit (PMMU) 209, Local Packet Memory (LPM) 219, Command Unit (CU) 213, Queuing System (QS) 211, Configuration Registers 221, and Register Transfer Unit (RTU) 227. The communication paths between elements of the PMU are indicated by arrows in FIG. 2, and further description of the elements of the PMU is provided below, including especially QS 211, which is a particular focus of the present patent application.

Overview of PMU

Again, FIG. 2 shows the elements of the PMU, which are identified briefly above. Packets arrive to the PMU in the present example through a 16-byte network input interface. In this embodiment packet data arrives to the PMU at a rate of 20 Gbps (max). At an operating speed of 300 MHz XCaliber core frequency, an average of 8 bytes of packet data are received every XCaliber core cycle. The incoming data from the network input interface is buffered in InBuffer (IB) block 207. Network interface 205 within XCaliber has the capability of appending to the packet itself the size of the packet being sent, in the event that the external device has not been able to append the size to the packet before sending the packet. Up to 2 devices can send packet data to XCaliber at (10 Gbps per device), and two in ports are shown from an attached ASIC. It is to be understood that the existence and use of the particular ASIC is exemplary, and packets could be received from other devices. Further, there may be in some embodiments more or fewer than the two in ports indicated.

Packet Memory Manager Unit (PMMU) 209 decides whether each incoming packet has to be stored into on-chip Local Packet Memory (LPM) 219, or, in the case that, for example, no space exists in the LPM to store it, may decide to either send the packet out to an External Packet Memory (EPM) not shown through the SIU block, or may decide to drop the packet. In case the packet is to be stored in the LPM, the PMMU decides where to store the packet and generates all the addresses needed to do so. The addresses generated correspond in a preferred embodiment to 16-byte lines in the LPM, and the packet is consecutively stored in this memory.

In the (most likely) case that the PMMU does not drop the incoming packet, a packet identifier is created, which includes a pointer (named packetPage) to a fixed-size page in packet memory where the packet has started to be stored. The identifier is created and enqueued into Queuing System (QS) block 211. The QS assigns a number from 0 to 255 (named packetNumber) to each new packet. The QS sorts the identifiers of the packets alive in XCaliber based on the priority of the packets, and it updates the sorting when the SPU core notifies any change on the status of a packet. The QS selects which packet identifiers will be provided next to the SPU. Again, the QS is a particular focus of the present application.

Register Transfer Unit (RTU) block 227, upon receiving a packet identifier (packetPage and packetNumber) from the QS, searches for an available context (229, FIG. 2) out of 8 contexts that XCaliber features in a preferred embodiment. For architectural and description purposes the contexts are considered a part of a broader Stream Processing Unit, although the contexts are shown in FIG. 2 as a separate unit 229.

In the case that no context is available, the RTU has the ability to notify the SPU about this event through a set of interrupts. In the case that a context is available, the RTU loads the packet identifier information and some selected fields of the header of the packet into the context, and afterwards it releases the context (which will at that time come under control of the SPU. The RTU accesses the header information of the packet through the SIU, since the packet could have been stored in the off-chip EPM.

Eventually a stream in the SPU core processes the context and notifies the QS of this fact. There are, in a preferred embodiment, eight streams in the DMS core. The QS then updates the status of the packet (to completed), and eventually this packet is selected for downloading (i.e. the packet data of the corresponding packet is sent out of the XCaliber processor to one of the two external devices).

When a packet is selected for downloading, the QS sends the packetPage (among other information) to the PMMU block, which generates the corresponding line addresses to read the packet data from the LPM (in case the packet was stored in the on-chip local memory) or it will instruct the SIU to bring the packet from the external packet memory to the PMU. In any case, the lines of packet data read are buffered into the OutBuffer (OB) block, and from there sent out to the device through the 16-byte network output interface. This interface is independent of its input counterpart. The maximum aggregated bandwidth of this interface in a preferred embodiment is also 20 Gbps, 10 Gbps per output device.

CommandUnit (CU) 213 receives commands sent by SPU 105. A command corresponds to a packet instruction, which are in many cases newly defined instructions, dispatched by the SPU core. These commands are divided into three independent types, and the PMU can execute one command per type per cycle (for a total of up to 3 commands per cycle). Commands can be load-like or store-like (depending on whether the PMU provides a response back to the SPU or not, respectively).

A large number of features of the PMU are configured by the SPU through memory-mapped configuration registers 221. Some such features have to be programmed at boot time, and the rest can be dynamically changed. For some of the latter, the SPU has to be running in a single-thread mode to properly program the functionality of the feature. The CU block manages the update of these configuration registers.

The PMU provides a mechanism to aid in flow control between ASIC 203 and XCaliber DMS processor 201. Two different interrupts are generated by the PMU to SPU 105 when LPM 219 or QS 211 are becoming full. Software controls how much in advance the interrupt is generated before the corresponding structure becomes completely full. Software can also disable the generation of these interrupts.

LPM 219 is also memory mapped, and SPU 105 can access it through the conventional load/store mechanism. Both configuration registers 221 and LPM 219 have a starting address (base address) kept by SIU 107. Requests from SPU 105 to LPM 219 and the configuration space arrive to the PMU through SIU block 107. The SIU is also aware of the base address of the external packet memory.

In Buffer (IB)

Packet data sent by an external device arrives to the PMU through the network input interface 205 at an average rate of 8 bytes every XCaliber core cycle in a preferred embodiment. IB block 207 of the PMU receives this data, buffers it, and provides it, in a FIFO-like fashion, to LPM 219 and in some cases also to the SIU (in case of a packet overflow, as explained elsewhere in this specification.

XCaliber DMS processor 201 can potentially send/receive packet data to/from up to 2 independent devices. Each device is tagged in SIU 107 with a device identifier, which is provided along with the packet data. When one device starts sending data from a packet, it will continue to send data from that very same packet until the end of the packet is reached or a bus error is detected by the SIU.

In a preferred embodiment the first byte of a packet always starts at byte 0 of the first 16 bytes sent of that packet. The first two bytes of the packet specify the size in bytes of the packet (including these first two bytes). These two bytes are always appended by the SIU if the external device has not appended them. If byte k in the 16-byte chunk is a valid byte, bytes 0 . . . k−1 are also valid bytes. This can be guaranteed since the first byte of a packet always starts at byte 0. Note that no valid bits are needed to validate each byte since a packet always starts at byte 0 of the 16-byte chunk, and the size of the packet is known up front (in the first two bytes). The network interface provides, at every core clock, a control bit specifying whether the 16-byte chunk contains, at least, one valid byte.

The valid data received from the network input interface is organized in buffer 207. This is an 8-entry buffer, each entry holding the 16-bytes of data plus the control bits associated to each chunk. PMMU 209 looks at the control bits in each entry and determines whether a new packet starts or to which of the (up to) two active packets the data belongs to, and it acts accordingly.

The 16-byte chunks in each of the entries in IB 207 are stored in LPM 219 or in the EPM (not shown). It is guaranteed by either the LPM controller or the SIU that the bandwidth to write into the packet memory will at least match the bandwidth of the incoming packet data, and that the writing of the incoming packet data into the packet memory will have higher priority over other accesses to the packet memory.

In some cases IB 207 may get full because PMMU 209 may be stalled, and therefore the LPM will not consume any more data of the IB until the stall is resolved. Whenever the IB gets full, a signal is sent to network input interface 205, which will retransmit the next 16-byte chunk as many times as needed until the IB accepts it. Thus, no packet data is lost due to the IB getting full.

Out Buffer (OB)

Network output interface 215 also supports a total aggregated bandwidth of 20 Gbps (10 Gbps per output device), as does the Input Interface. At 300 MHz XCaliber clock frequency, the network output interface accepts in average 8 bytes of data every XCaliber cycle from the OB block, and sends it to one of the two output devices. The network input and output interfaces are completely independent of each other.

Up to 2 packets (one per output device) can be simultaneously sent. The device to which the packet is sent does not need to correspond to the device that sent the packet in. The packet data to be sent out will come from either LPM 219 or the EPM (not shown).

For each of the two output devices connected at Network Out interface 215, PMMU 209 can have a packet ready to start being downloaded, a packet being downloaded, or no packet to download. Every cycle PMMU 209 selects the highest packet across both output devices and initiates the download of 16 bytes of data for that packet. Whenever the PMMU is downloading packet data from a packet to an output device, no data from a different packet will be downloaded to the same device until the current packet is completely downloaded.

The 16-byte chunks of packet data read from LPM 219 (along with some associated control information) are fed into one of the two 8-entry buffers (one per device identifier). The contents of the head of one of these buffers is provided to the network output interface whenever this interface requests it. When the head of both buffers is valid, the OB provides the data in a round robin fashion.

Differently than the network input interface, in the 16-byte chunk sent to the network output interface it can not be guaranteed that if a byte k is valid, then bytes 0 . . . k−1 are valid as well. The reason for this is that when the packet is being sent out, it does not need to start at byte 0 of the 16-byte chunk in memory. Thus, for each 16-byte chunk of data that contains the start of the packet to be sent out, OB 217 needs to notify the network interface where the first valid byte of the chunk resides. Moreover, since the first two bytes of the packet contain the size of the packet in bytes, the network output interface has the information to figure out where the last valid byte of the packet resides within the last 16-byte chunk of data for that packet. Moreover, OB 217 also provides a control bit that informs SIU 107 whether it needs to compute CRC for the packet, and if so, which type of CRC. This control bit is provided by PMMU 209 to OB 217.

Paging Memory Management Unit (PMMU)

The packet memory address space is 16 MB. Out of the 16 MB, the XCaliber processor features 256 KB on-chip. The rest (or a fraction) is implemented using external storage.

The packet memory address space can be mapped in the TLB of SPU 105 as user or kernel space, and as cacheable or uncacheable. In case it is mapped cacheable, the packet memory space is cached (write-through) into an L1 data cache of SPU 105, but not into an L2 cache.

A goal of PMMU 209 is to store incoming packets (and SPU-generated packets as well) into the packet memory. In case a packet from the network input interface fits into LPM 219, PMMU 209 decides where to store it and generates the necessary write accesses to LPM 219; in case the packet from the network input interface is going to be stored in the EPM, SPU 105 decides where in the EPM the packet needs to be stored and SIU 107 is in charge of storing the packet. In either case, the packet is consecutively stored and a packet identifier is created by PMMU 209 and sent to QS 211.

SPU 105 can configure LPM 219 so packets larger than a given size will never be stored in the LPM. Such packets, as well as packets that do not fit into the LPM because lack of space, are sent by PMMU 209 to the EPM through SIU 107. This is a mechanism called overflow and is configured by the SPU for the PMU to do so. If no overflow of packets is allowed, then the packet is dropped. In this case, PMMU 209 interrupts the SPU (again, if configured to do so).

Uploading a Packet into Packet Memory

Whenever there is valid data at the head of IB 205, the corresponding device identifier bit is used to determine to which packet (out of the two possible packets being received) the data belongs. When the network input interface starts sending data of a new packet with device identifier d, all the rest of the data will eventually arrive with that same device identifier d unless an error is notified by the network interface block. The network input interface can interleave data from two different device identifiers, but in a given cycle only data from one device is received by IB 207.

When a packet needs to be stored into LPM 219, PMMU block 209 generates all the write addresses and write strobes to LPM 219. If the packet needs to be stored into the EPM, SIU 107 generates them.

FIG. 3 is a diagram illustrating uploading of data into either LPM 219 or the EPM, which is shown in FIG. 3 as element 305, but not shown in FIG. 2. The write strobe to the LPM or EPM will not be generated unless the header of the IB has valid data. Whenever the write strobe is generated, the 16-byte chunk of data at the head of the IB (which corresponds to a LPM line) is deleted from the IB and stored in the LPM or EPM. The device identifier bit of the head of the IB is used to select the correct write address out of the 2 address generators (one per input device).

In the current embodiment only one incoming packet can be simultaneously stored in the EPM by the SIU (i.e. only one overflow packet can be handled by the SIU at a time). Therefore, if a second packet that needs to be overflowed is sent by the network input interface, the data of this packet will be thrown away (i.e. the packet will be dropped).

A Two Byte Packet-Size Header

The network input interface always appends two bytes to a packet received from the external device (unless this external device already does so, in which case the SIU will be programmed not to append them). This appended data indicates the size in bytes of the total packet, including the two appended bytes. Thus, the maximum size of a packet that is processed by the XCaliber DMS processor is 65535 bytes including the first two bytes.

The network output interface expects that, when the packet is returned by the PMU (if not dropped during its processing), the first two bytes also indicate the size of the processed packet. The size of the original packet can change (the packet can increase or shrink) as a result of processing performed by the XCaliber processor. Thus, if the processing results in increasing the size beyond 64K−1 bytes, it is the responsibility of software to chop the packet into two different smaller packets.

The PMU is more efficient when the priority of the packet being received is known up front. The third byte of the packet will be used for priority purpose if the external device is capable of providing this information to the PMU. The software programs the PMU to either use the information in this byte or not, which is does through a boot-time configuration register named Log2InQueues.

Dropping a Packet

A packet completely stored in either LPM 219 or EPM 305 will be dropped only if SPU 105 sends an explicit command to the PMU to do so. No automatic dropping of packets already stored in the packet memory can occur. In other words, any dropping algorithm of packets received by the XCaliber DMS processor is implemented in software.

There are, however, several situations wherein the PMU may drop an incoming packet. These are (a) The packet does not fit in the LPM and the overflow of packets is disabled, (b) The total amount of bytes received for the packet is not the same as the number of bytes specified by the ASIC in the first two bytes of the ASIC-specific header, or (c) A transmission error has occurred between the external device and the network input interface block of the SIU. The PMMU block is notified about such an error.

For each of the cases (a), (b) and (c) above, an interrupt is generated to the SPU. The software can disable the generation of these interrupts using AutomaticPacketDropIntEnable, PacketErrorIntEnable on-the-fly configuration flags.

Virtual Pages

An important process of PMMU 209 is to provide an efficient way to consecutively store packets into LPM 219 with as little memory fragmentation as possible. The architecture in the preferred embodiment provides SPU 105 with a capability of grouping, as much as possible, packets of similar size in the same region of LPM 219. This reduces overall memory fragmentation.

To implement the low-fragmentation feature, LPM 219 is logically divided into 4 blocks of 64 KB bytes each. Each block is divided into fixed atomic pages of 256 bytes. However, every block has virtual pages that range from 256 bytes up to 64 KB, in power-of-2 increments. Software can enable/disable the different sizes of the virtual pages for each of the 4 blocks using an on-the-fly configuration register named VirtualPageEnable. This allows configuring some blocks to store packets of up to a certain size.

The organization and features of the PMU assure that a packet of size s will never be stored in a block with a maximum virtual page size less than s. However, a block with a minimum virtual page size of r will accept packets of size smaller than r. This will usually be the case, for example, in which another block or blocks are configured to store these smaller packets, but is full.

Software can get ownership of any of the four blocks of the LPM, which implies that the corresponding 64 KB of memory will become software managed. A configuration flag exists per block (SoftwareOwned) for this purpose. The PMMU block will not store any incoming packet from the network input interface into a block in the LPM with the associated SoftwareOwned flag asserted. Similarly, the PMMU will not satisfy a GetSpace operation (described elsewhere) with memory of a block with its SoftwareOwned flag asserted. The PMMU, however, is able to download any packet stored by software in a software-owned block.

The PMMU logic determines whether an incoming packet fits in any of the blocks of the LPM. If a packet fits, the PMMU decides in which of the four blocks (since the packet may fit in more than one block), and the first and last atomic page that the packet will use in the selected block. The atomic pages are allocated for the incoming packet. When packet data stored in an atomic page has been safely sent out of the XCaliber processor through the network output interface, the corresponding space in the LPM can be de-allocated (i.e. made available for other incoming packets).

The EPM, like the LPM is also logically divided into atomic pages of 256 bytes. However, the PMMU does not maintain the allocation status of these pages. The allocation status of these pages is managed by software. Regardless of where the packet is stored, the PMMU generates an offset (in atomic pages) within the packet memory to where the first data of the packet is stored. This offset is named henceforth packetPage. Since the maximum size of the packet memory is 16 MB, the packetPage is a 16-bit value.

As soon as the PMMU safely stores the packet in the LPM, or receives acknowledgement from SIU 107 that the last byte of the packet has been safely stored in the EPM, the packetPage created for that packet is sent to the QS. Operations of the QS are described in enabling detail below.

Generating the PacketPage Offset

The PMMU always monitors the device identifier (deviceId) associated to the packet data at the head of the IB. If the deviceId is not currently active (i.e. the previous packet sent by that deviceId has been completely received), that indicates that the head of the IB contains the first data of a new packet. In this case, the first two bytes (byte0 and byte1 in the 16-byte chunk) specify the size of the packet in bytes. With the information of the size of the new incoming packet, the PMMU determines whether the packet fits into LPM 219 and, if it does, in which of the four blocks it will be stored, plus the starting and ending atomic pages within that block.

The required throughput in the current embodiment of the PMMU to determine whether a packet fits in LPM 219 and, if so, which atomic pages are needed, is one packet every two cycles. One possible two-cycle implementation is as follows: (a) The determination happens in one cycle, and only one determination happens at a time (b) In the cycle following the determination, the atomic pages needed to store the packet are allocated and the new state (allocated/de-allocated) of the virtual pages are computed. In this cycle, no determination is allowed.

FIG. 4 a is a diagram illustrating determination and allocation in parallel for local packet memory. The determination logic is performed in parallel for all of the four 64 KB blocks as shown.

FIG. 4 b shows the state that needs to be maintained for each of the four 64 KB blocks. This state, named AllocationMatrix, is recomputed every time one or more atomic pages are allocated or de-allocated, and it is an input for the determination logic. The FitsVector and IndexVector contain information computed from the AllocationMatrix.

AllocationMatrix[VPSize][VPIndex] indicates whether virtual page number VPIndex of size VPSize in bytes is already allocated or not. FitsVector[VPSize] indicates whether the block has at least one non-allocated virtual page of size VPSize. If FitsVector[VPSize] is asserted, IndexVector[VPSize] vector contains the index of a non-allocated virtual page of size VPSize.

The SPU programs which virtual page sizes are enabled for each of the blocks. The EnableVector[VPSize] contains this information. This configuration is performed using the VirtualPageEnable on-the-fly configuration register. Note that the AllocationMatrix[ ] [ ], FitsVector[ ], IndexVector[ ] and EnableVector[ ] are don't cares if the corresponding SoftwareOwned flag is asserted.

In this example the algorithm for the determination logic (for a packet of size s bytes) is as follows:

-   -   1) Fits logic: check, for each of the blocks, whether the packet         fits in or not. If it fits, remember the virtual page size and         the number of the first virtual page of that size.

For All Block j Do (can be done in parallel): Fits[j] = (s <= VPSize) AND FitsVector[VPSize] AND Not SoftwareOwned where VPSize is the smallest possible page size. If (Fits[j]) VPIndex[j] = IndexVector[VPSize] MinVPS[j] = VPSize Else MinVPS[j] = <Infinity>

2) Block selection: the blocks with the smallest virtual page (enabled or not) that is able to fit the packet in are candidates. The block with the smallest enabled virtual page is selected. If Fits[j] = FALSE for all j Then <Packet does not fit in LPM> packetPage = OverflowAddress >> 8 Else C = set of blocks with smallest MinVPS AND Fits[MinVPS] B = block# in C with the smallest enabled virtual page (if more than one exists, pick the smallest block number) If one or more blocks in C have virtual pages enabled Then Index = VPIndex[B] VPSize = MinVPS[B] NumAPs = ceil(S/256) packetPage = (B*64KB + Index*VPSize) >> Else <Packet does not fit in LPM> packetPage = OverflowAddress >> 8

If the packet fits in the LPM, the packetPage created is then the atomic page number within the LPM (there are up to 1K different atomic pages in the LPM) into which the first data of the packet is stored. If the packet does not fit, then the packetPage is the contents of the configuration register OverflowAddress right-shifted 8 bits. The packet overflow mechanism is described elsewhere in this specification, with a subheader “Packet overflow”.

In the cycle following the determination of where the packet will be stored, the new values of the AllocationMatrix, FitsVector and IndexVector must be recomputed for the selected block. If FitsVector[VPSize] is asserted, then IndexVector[VPSize] is the index of the largest non-allocated virtual page possible for the corresponding virtual page size. If FitsVector[VPSize] is de-asserted, then IndexVector[VPSize] is undefined.

The number of atomic pages needed to store the packet is calculated (NumAPs) and the corresponding atomic pages are allocated. The allocation of the atomic pages for the selected block (B) is done as follows:

-   -   1. The allocation status of the atomic pages in         AllocationMatrix[APsize] [j . . . k], j being the first atomic         page and k the last one (k−j+1=NumAPs), are set to allocated.     -   2. The allocation status of the virtual pages in         AllocationMatrix[r][s] are updated following the mesh structure         in FIG. 4 b. (a 2^(k+1)-byte virtual page will be allocated if         any of the two 2^(k)-byte virtual pages that it is composed of         is allocated).

When the packetPage has been generated, it is sent to the QS for enqueueing. If the QS is full (very rare), it will not be able to accept the packetPage being provided by the PMMU. In this case, the PMMU will not be able to generate a new packetPage for the next new packet. This puts pressure on the IB, which might get full if the QS remains full for several cycles.

The PMMU block also sends the queue number into which the QS has to store the packetPage. How the PMMU generates this queue number is described below in sections specifically allocated to the QS.

Page Allocation Example

FIGS. 5 a and 5 b illustrate an example of how atomic pages are allocated. For simplicity, the example assumes 2 blocks (0 and 1) of 2 KB each, with an Atomic page size of 256 bytes, and both blocks have their SoftwareOwned flag de-asserted. Single and double cross-hatched areas represent allocated virtual pages (single cross-hatched pages correspond to the pages being allocated in the current cycle). The example shows how the pages get allocated for a sequence of packet sizes of 256, 512, 1K and 512 bytes. Note that, after this sequence, a 2K-byte packet, for example, will not fit in the example LPM.

Whenever the FitsVector[VPSize] is asserted, the IndexVector[VPSize] contains the largest non-allocated virtual page index for virtual page size VPSize. The reason for choosing the largest index is that the memory space is better utilized. This is shown in FIGS. 6 a and 6 b, where two 256-byte packets are stored in a block. In scenario A, the 256-byte virtual page is randomly chosen, whereas in scenario B, the largest index is always chosen. As can be seen, the block in scenario A only allows two 512-byte virtual pages, whereas the block in scenario B allows three. Both, however, allow the same number of 256-byte packets since this is the smallest allocation unit. Note that the same effect is obtained by choosing the smallest virtual page index number all the time.

Packet Overflow

The only two reasons why a packet cannot be stored in the LPM are (a) that the size of the packet is larger than the maximum virtual page enabled across all 4 blocks; or (b) that the size of the packet is smaller than or equal to the maximum virtual page enabled but no space could be found in the LPM.

When a packet does not fit into the LPM, the PMMU will overflow the packet through the SIU into the EPM. To do so, the PMMU provides the initial address to the SIU (16-byte offset within the packet memory) to where the packet will be stored. This 20-bit address is obtained as follows: (a) The 16 MSB bits correspond to the 16 MSB bits of the OverflowAddress configuration register (i.e. the atomic page number within the packet memory). (b) The 4 LSB bits correspond to the HeaderGrowthOffset configuration register. The packetPage value (which will be sent to the QS) for this overflowed packet is then the 16 MSB bits of the OverflowAddress configuration register.

If the on-the-fly configuration flag OverflowEnable is asserted, the PMMU will generate an OverflowStartedInt interrupt. When the OverflowStartedint interrupt is generated, the size in bytes of the packet to overflow is written by the PMMU into the SPU-read-only configuration register SizeOfOverflowedPacket. At this point, the PMMU sets an internal lock flag that will prevent a new packet from overflowing. This lock flag is reset when the software writes into the on-the-fly configuration register OverflowAddress. If a packet needs to be overflowed but the lock flag is set, the packet will be dropped.

With this mechanism, it is guaranteed that only one interrupt will be generated and serviced per packet that is overflowed. This also creates a platform for software to decide where the starting address into which the next packet that will be overflowed will be stored is visible to the interrupt service routine through the SizeOfOverflowedPacket register. In other words, software manages the EPM.

If software writes the OverflowAddress multiple times in between two OverflowStartedint interrupts, the results are undefined. Moreover, if software sets the 16 MSB bits of OverflowAddress to 0.1023, results are also undefined since the first 1K atomic pages in the packet memory correspond to the LPM.

Downloading a Packet from Packet Memory

Eventually the SPU will complete the processing of a packet and will inform the QS of the fact. At this point the packet may be downloaded from memory, either LPM or EPM, and sent, via the OB to one of the connected devices. FIG. 7 is a top-level schematic of the blocks of the XCaliber DMS processor involved in the downloading of a packet, and the elements in FIG. 7 are numbered the same as in FIG. 2. The downloading process may be followed in FIG. 7 with the aid of the following descriptions.

When QS 211 is informed that processing of a packet is complete, the QS marks this packet as completed and, a few cycles later (depending on the priority of the packet), the QS provides to PMMU 209 (as long as the =PMMU has requested it) the following information regarding the packet:

(a) the packetPage

(b) the priority (cluster number from which it was extracted)

(c) the tail growth/shrink information (described later in spec)

(d) the outbound device identifier bit

(e) the CRC type field (described later in spec)

(f) the KeepSpace bit

The device identifier sent to PMMU block 209 is a 1-bit value that specifies the external device to which the packet will be sent. This outbound device identifier is provided by software to QS 211 as a 2-bit value.

If the packet was stored in LPM 219, PMMU 209 generates all of the (16-byte line) read addresses and read strobes to LPM 219. The read strobes are generated as soon as the read address is computed and there is enough space in OB 217 to buffer the line read from LPM 219. Buffer d in the OB is associated to device identifier d. This buffer may become full for either two reasons: (a) The external device d temporarily does not accept data from XCaliber; or (b) The rate of reading data from the OB is lower than the rate of writing data into it.

As soon as the packet data within an atomic page has all been downloaded and sent to the OB, that atomic page can be de-allocated. The de-allocation of one or more atomic pages follows the same procedure as described above. However, no de-allocation of atomic pages occurs if the LPM bit is de-asserted. The KeepSpace bit is a don't care if the packet resides in EPM 701.

If the packet was stored in EPM 701, PMMU 209 provides to SIU 107 the address within the EPM where the first byte of the packet resides. The SIU performs the downloading of the packet from the EPM. The SIU also monitors the buffer space in the corresponding buffer in OB 217 to determine whether it has space to write the 16-byte chunk read from EPM 701. When the packet is fully downloaded, the SIU informs the PMMU of the fact so that the PMMU can download the next packet with the same device identifier.

When two packets (one per device) are being simultaneously sent, data from the packet with highest priority is read out of the memory first. This preemption can happen at a 16-byte boundary or when the packet finishes its transmission. If both packets have the same priority (provided by the QS), a round-robin method is used to select the packet from which data will be downloaded next. This selection logic also takes into account how full the two buffers in the OB are. If buffer d is full, for example, no packet with a device identifier d will be selected in the PMMU for downloading the next 16-byte chunk of data.

When a packet starts to be downloaded from the packet memory (local or external), the PMMU knows where the first valid byte of the packet resides. However, the packet's size is not known until the first line (or the first two lines in some cases) of packet data is read from the packet memory, since the size of the packet resides in the first two bytes of the packet data. Therefore, the processing of downloading a packet first generates the necessary line addresses to determine the size of the packet, and then, if needed, generates the rest of the accesses.

This logic takes into account that the first two bytes that specify the size of the packet can reside in any position in the 16-byte line of data. A particular case is when the first two bytes span two consecutive lines (which will occur when the first byte is the 16th byte of a line, and second byte is the 1^(st) byte of next line.

As soon as the PMMU finishes downloading a packet (all the data of that packet has been read from packet memory and sent to OB), the PMMU notifies the QS of this event. The QS then invalidates the corresponding packet from its queuing system.

When a packet starts to be downloaded, it cannot be preempted, i.e. the packet will finish its transmission. Other packets that become ready to be downloaded with the same outbound device identifier while the previous packet is being transmitted cannot be transmitted until the previous packet is fully transmitted.

Packet Growth/Shrink

As a result of processing a packet, the size of a network packet can grow, shrink or remain the same size. If the size varies, the SPU has to write the new size of the packet in the same first two bytes of the packet. The phenomenon of packet growth and shrink is illustrated in FIG. 8.

Both the header and the tail of the packet can grow or shrink. When a packet grows, the added data can overwrite the data of another packet that may have been stored right above the packet experiencing header growth, or that was stored right below in the case of tail growth. To avoid this problem the PMU can be configured so that an empty space is allocated at the front and at the end of every packet when it is stored in the packet memory. These empty spaces are specified with HeaderGrowthOffset and TailGrowthOffset boot-time configuration registers, respectively, and their granularity is 16 bytes. The maximum HeaderGrowthOffset is 240 bytes (15 16-byte chunks), and the maximum TailGrowthOffset is 1008 bytes (63 16-byte chunks). The minimum in both cases is 0 bytes. Note that these growth offsets apply to all incoming packets, that is, there is no mechanism to apply different growth offsets to different packets.

When the PMMU searches for space in the LPM, it will look for contiguous space of Size(packet)+((HeaderGrowthOffset+TailGrowthOffset)<<4). Thus, the first byte of the packet (first byte of the ASIC-specific header) will really start at offset ((packetPage<<8)+(HeaderGrowthOffset<<4)) within the packet memory.

The software knows what the default offsets are, and, therefore, knows how much the packet can safely grow at both the head and the tail. In case the packet needs to grow more than the maximum offsets, the software has to explicitly move the packet to a new location in the packet memory. The steps to do this are as follows:

-   -   1) The software requests the PMU for a chunk of contiguous space         of the new size. The PMU will return a new packetPage that         identifies (points to) this new space.     -   2) The software writes the data into the new memory space.     -   3) The software renames the old packetPage with the new         packetPage.     -   4) The software requests the PMU to de-allocate the space         associated to the old packetPage.

In the case of header growth or shrinkage, the packet data will no longer start at ((packetPage<<8)+(HeaderGrowthOffset<<4)). The new starting location is provided to the PMU with a special instruction executed by the SPU when the processing of the packet is completed. This information is provided to the PMMU by the QS block.

Time Stamp

The QS block of the PMU (described in detail in a following section) guarantees the order of the incoming packets by keeping the packetPage identifiers of the packets in process in the XCaliber processor in FIFO-like queues. However, software may break this ordering by explicitly extracting identifiers from the QS, and inserting them at the tail of any of the queues.

To help software in guaranteeing the relative order of packets, the PMU can be configured to time stamp every packet that arrives to the PMMU block using an on-the-fly configuration flag TimeStampEnabled. The time stamp is an 8-byte value, obtained from a 64-bit counter that is incremented every core clock cycle.

When the time stamp feature is on, the PMMU appends the 8-byte time stamp value in front of each packet, and the time stamp is stripped off when the packet is sent to the network output interface. The time stamp value always occupies the 8 MSB bytes of the (k−1)th 16-byte chunk of the packet memory, where k is the 16-byte line offset where the data of the packet starts (k>0). In the case that HeaderGrowthOffset is 0, the time stamp value will not be appended, even if TimeStampEnabled is asserted.

The full 64-bit time counter value is provided to software through a read-only configuration register (TimeCounter).

Software Operations on the PMMU

Software has access to the PMMU to request or free a chunk of contiguous space. In particular, there are two operations that software can perform on the PMMU. Firstly the software, through an operation GetSpace(size), may try to find a contiguous space in the LPM for size bytes. The PMU replies with the atomic page number where the contiguous space that has been found starts (i.e. the packetPage), and a success bit. If the PMU was able to find space, the success bit is set to ‘1’, otherwise it is set to ‘0’. GetSpace will not be satisfied with memory of a block that has its SoftwareOwned configuration bit asserted. Thus, software explicitly manages the memory space of software-owned LPM blocks.

The PMMU allocates the atomic pages needed for the requested space. The EnableVector set of bits used in the allocation of atomic pages for incoming packets is a don't care for the GetSpace operation. In other words, as long as sufficient consecutive non-allocated atomic pages exist in a particular block to cover size bytes, the GetSpace(size) operation will succeed even if all the virtual pages in that block are disabled. Moreover, among non-software-owned blocks, a GetSpace operation will be served first using a block that has all its virtual pages disabled. If more than such a block exists, the smallest block number is chosen. If size is 0, GetSpace(size) returns ‘0’.

The second operation software can perform on the PMMU is FreeSpace(packetPage). In this operation the PMU de-allocates atomic pages that were previously allocated (starting at packetPage). This space might have been either automatically allocated by the PMMU as a result of an incoming packet, or as a result of a GetSpace command. FreeSpace does not return any result to the software. A FreeSpace operation on a block with its SoftwareOwned bit asserted is disregarded (nothing is done and no result will be provided to the SPU).

Local Packet Memory

Local Packet Memory (LPM), illustrated as element 219 in FIGS. 2 and 7, has in the instant embodiment a size of 256 KB, 16-byte line width with byte enables, 2 banks (even/odd), one Read and one Write port per bank, is fully pipelined, and has one cycle latency

The LPM in packet processing receives read and write requests from both the PMMU and the SIU. An LPM controller guarantees that requests from the PMMU have the highest priority. The PMMU reads at most one packet while writing another one. The LPM controller guarantees that the PMMU will always have dedicated ports to the LPM.

Malicious software could read/write the same data that is being written/read by the PMMU. Thus, there is no guarantee that the read and write accesses in the same cycle are performed to different 16-byte line addresses.

A request to the LPM is defined in this example as a single access (either read or write) of 16-bytes. The SIU generates several requests for a masked load or store, which are new instructions known to the inventors and the subject of at least one separate patent application. Therefore, a masked load/store operation can be stalled in the middle of these multiple requests if the highest priority PMMU access needs the same port.

When the PMMU reads or writes, the byte enable signals are assumed to be set (i.e. all 16 bytes in the line are either read or written). When the SIU drives the reads or writes, the byte enable signals are meaningful and are provided by the SIU.

When the SPU reads a single byte/word in the LPM, the SIU reads the corresponding 16-byte line and performs the extraction and right alignment of the desired byte/word. When the SPU writes a single byte/word, the SIU generates a 16-byte line with the byte/word in the correct location, plus the valid bytes signals.

Prioritization Among Operations

The PMMU may receive up to three requests from three different sources (IB, QS and software) to perform operations. For example, requests may come from the IB and/or Software: to perform a search for a contiguous chunk of space, to allocate the corresponding atomic page sizes and to provide the generated packetPage. Requests may also come from the QS and/or Software to perform the de-allocation of the atomic pages associated to a given packetPage.

It is required that the first of these operations takes no more than 2 cycles, and the second no more than one. The PMMU executes only one operation at a time. From highest to lowest, the PMMU block will give priority to requests from: IB, QS and Software.

Early Full-PMMU Detection

The PMU implements a mechanism to aid in flow control between any external device and the XCaliber processor. Part of this mechanism is to detect that the LPM is becoming fill and, in this case, a NoMorePagesOfXsizeInt interrupt is generated to the SPU. The EPM is software controlled and, therefore, its state is not maintained by the PMMU hardware.

The software can enable the NoMorePagesOfXsizeInt interrupt by specifying a virtual page size s. Whenever the PMMU detects that no more available virtual pages of that size are available (i.e. FitsVector[s] is de-asserted for all the blocks), the interrupt is generated. The larger the virtual page size selected, the sooner the interrupt will be generated. The size of the virtual page will be indicated with a 4-bit value (0:256 bytes, 1:512 bytes, . . . , 8:64 KB) in an on-the-fly configuration register IntIfNoMoreThanXsizePages. When this value is greater than 8, the interrupt is never generated.

If the smallest virtual page size is selected (256 bytes), the NoMorePagesOfXsizeInt interrupt is generated when the LPM is completely full (i.e. no more packets are accepted, not even a 1-byte packet).

In general, if the IntIfNoMoreThanXsizePages is X, the soonest the interrupt will be generated is when the local packet memory is (100/2^(X))% full. Note that, because of the atomic pages being 256 bytes, the LPM could become full with only 3 K-bytes of packet data (3 byte per packet, each packet using an atomic page).

Packet Size Mismatch

The PMMU keeps track of how many bytes are being uploaded into the LPM or EPM. If this size is different from the size specified in the first two bytes, a PacketErrorInt interrupt is generated to the SPU. In this case the packet with the mismatch packet size is dropped (the already allocated atomic pages will be de-allocated and no packetPage will be created). No AutomaticDropInt interrupt is generated in this case. If the actual size is more than the size specified in the first two bytes, the remaining packet data being received from the ASIC is gracefully discarded.

When a packet size mismatch is detected on an inbound device identifier D (D=0,1), the following packets received from that same device identifier are dropped until software writes (any value) into a ClearErrorD configuration register.

Bus Error Recovering

Faulty packet data can arrive to or leave the PMU due to external bus errors. In particular the network input interface may notify that the 16-byte chunk of data sent in has a bus error, or the SIU may notify that the 16-byte chunk of data downloaded from EPM has a bus error. In both cases, the PMMU generates the PacketErrorInt interrupt to notify the SPU about this event. No other information is provided to the SPU.

Note that if an error is generated within the LPM, it will not be detected since no error detection mechanism is implemented in this on-chip memory. Whenever a bus error arises, no more data of the affected packet will be received by the PMU. This is done by the SIU in both cases. For the first case the PMMU needs to de-allocate the already allocated atomic pages used for the packet data received previous to the error event.

When a bus error is detected on an inbound device identifier D (D=0,1), the following packets received from that same device identifier are dropped until software writes (any value) into a ClearErrorD (D=0,1) configuration register.

Queuing System (QS)

The queuing system (QS) in the PMU of the XCaliber processor has functions of holding packet identifiers and the state of the packets currently in-process in the XCaliber processor, keeping packets sorted by their default or software-provided priority, selecting the packets that need to be pre-loaded (in the background) into one of the available contexts, and selecting those processed packets that are ready to be sent out to an external device.

FIG. 9 is a block diagram showing the high-level communication between the QS and other blocks in the PMU and SPU. When the PMMU creates a packetPage, it is sent to the QS along with a queue number and the device identifier. The QS enqueues that packetPage in the corresponding queue and associates a number (packetNumber) to that packet. Eventually, the packet is selected and provided to the RTU, which loads the packetPage, packetNumber and selected fields of the packet header into an available context. Eventually the SPU processes that context and communicates to the PMU, among other information, when the processing of the packet is completed or the packet has been dropped. For this communication, the SPU provides the packetNumber as the packet identifier. The QS marks that packet as completed (in the first case) and the packet is eventually selected for downloading from packet memory.

It is a requirement in the instant embodiment (and highly desirable) that packets of the same flow (same source and destination) need to be sent out to the external device in the same order as they arrived to the XCaliber processor (unless software explicitly breaks this ordering). When the SPU begins to process a packet the flow is not known. Keeping track of the ordering of packets within a flow is a costly task because of the amount of processing needed and because the number of active flows can be very large, depending on the application. Thus, the order within a flow is usually kept track by using aggregated-flow queues. In an aggregated-flow queue, packet identifiers from different flows are treated as from the same flow for ordering purposes.

The QS offloads the costly task of maintaining aggregated-flow queues by doing it in hardware and in the background. Up to 32 aggregated-flow queues can be maintained in the current embodiment, and each of these queues has an implicit priority. Software can enqueue a packetPage in any of the up to 32 queues, and can move a packetPage identifier from one queue to another (for example, when the priority of that packet is discovered by the software). It is expected that software, if needed, will enqueue all the packetPage identifiers of the packets that belong to the same flow into the same queue. Otherwise, a drop in the performance of the network might occur, since packets will be sent out of order within the same flow. Without software intervention, the QS guarantees the per-flow order of arrival.

Generic Queue

The QS implements a set of up to 32 FIFO-like queues, which are numbered, in the case of 32 queues, from 0 to 31. Each queue can have up to 256 entries. The addition of all the entries of all the queues, however, cannot exceed 256. Thus, queue sizes are dynamic. A queue entry corresponds to a packetPage identifier plus some other information. Up to 256 packets are therefore allowed to be in process at any given time in the XCaliber processor. This maximum number is not visible to software.

Whenever the QS enqueues a packetPage, a number (packetNumber) from 0 to 255 is assigned to the packetPage. This number is provided to the software along with the packetPage value. When the software wants to perform an operation on the QS, it provides the packetNumber identifier. This identifier is used by the QS to locate the packetPage (and other information associated to the corresponding packet) in and among its queues.

Software is aware that the maximum number of queues in the XCaliber processor is 32. Queues are disabled unless used. That is, the software does not need to decide how many queues it needs up front. A queue becomes enabled when at least one packet is in residence in that queue.

Several packet identifiers from different queues can become candidates for a particular operation to be performed. Therefore, some prioritization mechanism must exist to select the packet identifier to which an operation will be applied first. Software can configure (on-the-fly) the relative priority among the queues using an “on-the-fly” configuration register PriorityClusters. This is a 3-bit value that specifies how the different queues are grouped in clusters. Each cluster has associated a priority (the higher the cluster number, the higher the priority). The six different modes in the instant embodiment into which the QS can be configured are shown in the table of FIG. 10.

The first column of FIG. 10 is the value in the “on-the-fly” configuration register PriorityClusters. Software controls this number, which defines the QS configuration. For example, for PriorityClusters=2, the QS is configured into four clusters, with eight queues per cluster. The first of the four clusters will have queues 0 through 7, the second cluster will have queues 8-15, the third clusters 16 through 23, and the last of the four clusters has queues 24 through 31.

Queues within a cluster are treated fairly in a round robin fashion. Clusters are treated in a strict priority fashion. Thus, the only mode that guarantees no starvation of any queue is when PriorityClusters is 0, meaning one cluster of 32 queues.

Inserting a PacketPage/DeviceId into the QS

FIG. 11 is a diagram illustrating the generic architecture of QS 211 of FIGS. 2 and 7 in the instant embodiment. Insertion of packetPages and DeviceId information is shown as arrows directed toward the individual queues (in this case 32 queues). The information may be inserted from three possible sources, these being the PMMU, the SPU and re-insertion from the QS. There exists priority logic, illustrated by function element 1101, for the case in which two or more sources have a packetPage ready to be inserted into the QS. In the instant embodiment the priority is, in descending priority order, the PMMU, the QS, and the SPU (software).

Regarding insertion of packets from the SPU (software), the software can create packets on its own. To do so, it first requests a consecutive chunk of free space of a given size (see the SPU documentation) from the PMU, and the PMU returns a packetPage in case the space is found. The software needs to explicitly insert that packetPage for the packet to be eventually sent out. When the QS inserts this packetPage, the packetNumber created is sent to the SPU. Software requests an insertion through the Command Unit (see FIG. 2).

In the case of insertion from the QS, an entry residing at the head of a queue may be moved to the tail of another queue. This operation is shown as selection function 1103.

In the case of insertion from the PMU, when a packet arrives to the XCaliber processor, the PMMU assigns a packetPage to the packet, which is sent to the QS as soon as the corresponding packet is safely stored in packet memory.

An exemplary entry in a queue is illustrated as element 1105, and has the following fields: Valid (1) validates the entry. PacketPage (16) is the first atomic page number in memory used by the packet. NextQueue (5) may be different from the queue number the entry currently belongs to, and if so, this number indicates the queue into which the packetPage needs to be inserted next when the entry reaches the head of the queue. Delta (10) contains the number of bytes that the header of the packet has either grown or shrunk. This value is coded in 2's complement. Completed (1) is a single bit that indicates whether software has finished the processing of the corresponding packet. DeviceId (2) is the device identifier associated to the packet. Before a Complete operation is performed on the packet (described below) the DeviceId field contains the device identifier of the external device that sent the packet in. After the Complete operation, this field contains the device identifier of the device to which the packet will be sent. Active (1) is a single bit that indicates whether the associated packet is currently being processed by the SPU. CRCtype (2) indicates to the network output interface which type of CRC, if any, needs to be computed for the packet. Before the Complete operation is performed on the packet, this field is 0. KeepSpace (1) specifies whether the atomic pages that the packet occupies in the LPM will be de-allocated (KeepSpace de-asserted) by the PMMU or not (KeepSpace asserted). If the packet resides in EPM this bit is disregarded by the PMMU.

The QS needs to know the number of the queue to which the packetPage will be inserted. When software inserts the packetPage, the queue number is explicitly provided by an XStream packet instruction, which is a function of the SPU, described elsewhere in this specification. If the packetPage is inserted by the QS itself, the queue number is the value of the NextQueue field of the entry where the packetPage resides.

When a packetPage is inserted by the PMMU, the queue number depends on how the software has configured (at boot time) the Log2InputQueues configuration register. If Log2InputQueues is set to 0, all the packetPages for the incoming packets will be enqueued in the same queue, which is specified by the on-the-fly configuration register FirstInputQueue. If Log2InputQueues is set to k (1<=k<=5), then the k MSB bits of the 3rd byte of the packet determine the queue number. Thus an external device (or the network input interface block of the SIU) can assign up to 256 priorities for each of the packets sent into the PMU. The QS maps those 256 priorities into 2^(k), and uses queue numbers FirstInputQueue to FirstInputQueue+2^(k−)1 to insert the packetPages and deviceId information of the incoming packets.

It is expected that an external device will send the same 5 MSB bits in the 3^(rd) byte for all packets in the same flow. Otherwise, a drop in the performance of the network might occur, since packets may be sent back to the external device out-of-order within the same flow. Software is aware of whether or not the external device (or SIU) can provide the information of the priority of the packet in the 3^(rd) byte.

When packetPage p is inserted into queue q, the PacketPage field of the entry to be used is set to p and the Valid field to ‘1’. The value for the other fields depend on the source of the insertion. If the source is software (SPU), Completed is ‘0’; NextQueue is provided by SPU; DeviceId is ‘0’; Active is ‘1’; CRCtype is 0; KeepSpace is 0, and Probed is 0.

If the source is the QS, the remaining fields are assigned the value they have in the entry in which the to-be-inserted packetPage currently resides. If the source is the PMMU, Completed is ‘0’, NextQueue is q, DeviceId is the device identifier of the external device that sent the packet into XCaliber, Active is ‘0’, CRCtype is 0, KeepSpace is 0, and Probed is 0.

Monitoring Logic

The QS monitors entries into all of the queues to detect certain conditions and to perform the corresponding operation, such as to re-enqueue an entry, to send a packetPage (plus some other information) to the PMMU for downloading, or to send a packetPage (plus some other information) to the RTU.

All detections take place in a single cycle and they are done in parallel.

Re-Enqueuing an Entry

The QS monitors all the head entities of the queues to determine whether a packet needs to be moved to another queue. Candidate entries to be re-enqueued need to be valid, be at the head of a queue, and have the NextQueue field value different from the queue number of the queue in which the packet currently resides.

If more than one candidate exists for re-enqueueing, the chosen entry will be selected following a priority scheme described later in this specification.

Sending an Entry to the PMMU for Downloading

The QS monitors all the head entities of the queues to determine whether a packet needs to be downloaded from the packet memory. This operation is 1102 in FIG. 11. The candidate entries to be sent out of XCaliber need to be valid, be at the head of the queue, have the NextQueue field value the same as the queue number of the queue in which the packet currently resides, and have the Completed flag asserted and the Active flag de-asserted. Moreover the QS needs to guarantee that no pending reads or writes exist from the same context that has issued the download command to the QS.

If more than one candidate exists for downloading, the chosen entry will be selected following a priority scheme described later in this specification.

A selected candidate will only be sent to the PMMU if the PMMU requested it. If the candidate was requested, the selected packetPage, along with the cluster number from which it is extracted, the tail growth/shrink, the outbound device identifier bit, the CRCtype and the KeepSpace bits are sent to the PMMU.

FIG. 12 is a table indicating coding of the Deviceid field. If the Deviceid field is 0, then the Outbound Device Identifier is the same as the Inbound Device Identifier, and so on as per the table.

When an entry is sent to the PMMU, the entry is marked as “being transmitted” and it is extracted from the queuing system (so that it does not block other packets that are ready to be transmitted and go to a different outbound device identifier). However, the entry is not invalidated until the PMMU notifies that the corresponding packet has been completely downloaded. Thus, probe-type operations on this entry will be treated as valid, i.e. as still residing in the XCaliber processor.

Reincarnation Effect

As described above, the QS assigns a packetNumber from 0 to 255 (256 numbers in total) to each packet that comes into XCaliber and is inserted into a queue. This is done by maintaining a table of 256 entries into which packet identifiers are inserted. At this time the Valid bit in the packet identifier is also asserted. Because the overall numbers of packets dealt with by XCaliber far exceeds 256, packet numbers, of course, have to be reused throughout the running of the XCaliber processor. Therefore, when packets are selected for downloading, at some point the packetNumber is no longer associated with a valid packet in process, and the number may be reused.

As long as a packet is valid in XCaliber it is associated with the packetNumber originally assigned. The usual way in which a packetNumber becomes available to be reused is that a packet is sent by the QS to the RTU for preloading in a context prior to processing. Then when the packet is fully processed and fully downloaded from memory, the packet identifier in the table associating packetNumbers is marked Invalid by manipulating the Valid bit (see FIG. 11 and the text accompanying).

In usual operation the system thus far described is perfectly adequate. It has been discovered by the inventors, however, that there are some situations in which the Active and Valid bits are not sufficient to avoid contention between streams. One of these situations has to do with a clean-up process, sometimes termed garbage collection, in which software monitors all packet numbers to determine when packets have remained in the system too long, and discards packets under certain conditions, freeing space in the system for newly-arriving packets.

In these special operations, like garbage collection, a stream must gain ownership of a packet, and assure that the operation it is to perform on the packet actually gets performed on the correct packet. As software probes packets, however, and before action may be taken, because there are several streams operating, and because the normal operation of the system may also send packets to the RTU, for example, it is perfectly possible in these special operations that a packet probed may be selected and effected by another stream before the special operation is completed. A packet, for example, may be sent to the RTU, processed, and downloaded, and a new packet may then be assigned to the packetNumber, and the new packet may even be stored at exactly the same packetPage as the original packet. There is a danger, then, that the special operations, such as discarding a packet in the garbage collection process, may discard a new and perfectly valid packet, instead of the packet originally selected to be discarded. This, of course, is just one of potentially many such special operations that might lead to trouble.

Considering the above, the inventors have provided a mechanism for assuring that, given two different absolute points in time, time s and time r, for example, that a valid packetNumber at time s and the same packetNumber at time r, still is associated to the same packet. A simple probe operation is not enough, because at some time after s and before time r the associated packet may be downloaded, and another (and different) packet may have arrived, been stored in exactly the same memory location as the previous packet, and been assigned the same packetNumber as the downloaded packet.

The mechanism implemented in XCaliber to ensure packetNumber association with a specific packet at different times includes a probe bit in the packet identifier. When a first stream, performing a process such as garbage collection, probes a packet, a special command, called Probe&Set is used. Probe&Set sets (asserts) the probe bit, and the usual information is returned, such as the value for the Valid bit, the Active bit, the packetPage address, and the old value of the probe bit. The first stream then executes a Conditional Activate instruction, described elsewhere in this specification, to gain ownership of the packet. Also, when the queuing system executes this Conditional Activate instruction it asserts the active bit of the packet. Now, at any time after the probe bit is set by the first stream, when a second stream at a later time probes the same packet, the asserted probe bit indicates that the first stream intends to gain control of this packet. The second stream now knows to leave this packet alone. This probe bit is de-asserted when a packet enters the XCaliber processor and a new (non-valid) number is assigned.

Sending an Entry to the RTU

The RTU uploads in the SPU background to the XCaliber processor some fields of the headers of packets that have arrived, and have been completely stored into packet memory. This uploading of the header of a packet in the background may occur multiple times for the same packet. The QS keeps track of which packets need to be sent to the RTU. The selection operation is illustrated in FIG. 11 as 1104.

Whenever the RTU has chosen a context to pre-load a packet, it notifies the QS that the corresponding packet is no longer an inactive packet. The QS then marks the packet as active.

Candidate entries to be sent to the RTU need to be valid, to be the oldest entry with the Active and Completed bits de-asserted, to have the NextQueue field value the same as the queue number of the queue in which the packet currently resides, and to conform to a limitation that no more than a certain number of packets in the queue in which the candidate resides are currently being processed in the SPU. More detail regarding this limitation is provided later in this specification. When an entry is sent to the RTU for pre-loading, the corresponding Active bit is asserted.

A queue can have entries with packet identifiers that already have been presented to the RTU and entries that still have not. Every queue has a pointer (NextPacketForRTU) that points to the oldest entry within that queue that needs to be sent to the RTU. Within a queue, packet identifiers are sent to the RTU in the same order they were inserted in the queue.

The candidate packet identifiers to be sent to the RTU are those pointed to by the different NextPacketForRTU pointers associated with the queues. However, some of these pointers might point to a non-existent entry (for example, when the queue is empty or when all the entries have already been sent to the RTU). The hardware that keeps track of the state of each of the queues determines these conditions. Besides being a valid entry pointed to by a NextPacketForRTU pointer, the candidate entry needs to have associated with it an RTU priority (described later in this specification) currently not being used by another entry in the RTU. If more than a single candidate exists, the chosen entry is selected following a priority scheme described later in this specification.

As opposed to the case in which an entry is sent to the PMMU for downloading, an entry sent to the RTU is not extracted from its queue. Instead, the corresponding NextPacketForRTU pointer is updated, and the corresponding Active bit is asserted.

The QS sends entries to an 8-entry table in the RTU block as long as the entry is a valid candidate and the corresponding slot in the RTU table is empty. The RTU will accept, at most, 8 entries, one per each interrupt that the RTU may generate to the SPU.

The QS maps the priority of the entry (given by the queue number where it resides) that it wants to send to the RTU into one of the 8 priorities handled by the RTU (RTU priorities). This mapping is shown in the table of FIG. 13, and it depends on the number of clusters into which the different queues are grouped (configuration register PriorityClusters) and the queue number in which the entry resides.

The RTU has a table of 8 entries, one for each RTU priority. Every entry contains a packet identifier (packetPage, packetNumber, queue#) and a Valid bit that validates it. The RTU always accepts a packet identifier of RTU priority p if the corresponding Valid bit in entry p of that table is de-asserted. When the RTU receives a packet identifier of RTU priority p from the QS, the Valid bit of entry p in the table is asserted, and the packet identifier is stored. At that time the QS can update the corresponding NextPacketForRTU pointer.

Limiting the Packets Sent within a Queue

Software can limit the number of packets that can be active (i.e. being processed by any of the streams in the SPU) on a per-queue basis. This is achieved through a MaxActivePackets on-the-fly configuration register, which specifies, for each queue, a value between 1 and 256 that corresponds to the maximum number of packets, within that queue, that can be being processed by any stream.

The QS maintains a counter for each queue q which keeps track of the current number of packets active for queue q. This counter is incremented whenever a packet identifier is sent from queue q to the RTU, a Move operation moves a packet into queue q, or an Insert operation inserts a packet identifier into queue q; and decremented when any one the following operations are performed in any valid entry in queue q: a Complete operation, an Extract operation, a Move operation that moves the entry to a different queue, or a MoveAndReactivate operation that moves the entry to any queue (even to the same queue). Move, MoveAndReactivate, Insert, Complete and Extract are operations described elsewhere in this specification.

Whenever the value of the counter for queue q is equal to or greater than the corresponding maximum value specified in the MaxActivePackets configuration register, no entry from queue q is allowed to be sent to the RTU. The value of the counter could be greater since software can change the MaxActivePackets configuration register for a queue to a value lower than the counter value at the time of the change, and a queue can receive a burst of moves and inserts.

Software Operations on the QS

Software executes several instructions that affect the QS. The following is a list of all operations that can be generated to the QS as a result of the dispatch by the SPU core of an XStream packet instruction:

Insert(p,q): the packetPage p is inserted into queue q. A ‘1’ will be returned to the SPU if the insertion was successful, and a ‘0’ if not. The insertion will be unsuccessful only when no entries are available (i.e. when all the 256 entries are valid).

Move(n,q): asserts to q the NextQueue field of the entry in which packetNumber n resides.

MoveAndReactivate(n,q): asserts to q the NextQueue field of the entry in which packetNumber n resides; de-asserts the Active bit.

Complete(n,d,e): asserts the Completed flag, the Delta field to d and the deviceId field to e of the entry in which packetNumber n resides. De-asserts the Active bit and de-asserts the KeepSpace bit.

CompleteAndKeepSpace(n,d,e): same as Complete( ) but it asserts the KeepSpace bit.

Extract(n): resets the Valid flag of the entry in which packetNumber n resides.

Replace(n,p): the PacketPage field of the entry in which packetNumber n resides is set to packetPage p.

Probe(n): the information whether the packetNumber n exists in the QS or not is returned to the software. In case it exists, it returns the PacketPage, Completed, NextQueue, DeviceId, CRCtype, Active, KeepSpace and Probed fields.

ConditionalActivate(n): returns a ‘1’ if the packetNumber n is valid, Probed is asserted, Active is de-asserted, and the packet is not being transmitted. In this case, the Active bit is asserted.

The QS queries the RTU to determine whether the packet identifier of the packet to be potentially activated is in the RTU table, waiting to be preloaded, or being preloaded. If the packet identifier is in the table, the RTU invalidates it. If the query happens simultaneously with the start of preloading of that packet, the QS does not activate the packet.

ProbeAndSet(n): same as Probe( ) but it asserts the Probed bit (the returned Probed bit is the old Probed bit).

Probe(q): provides the size (i.e. number of valid entries) in queue q.

A Move( ), MoveAndReactivate( ), Complete( ), CompleteAndKeepSpace( ), Extract( ) and Replace( ) on an invalid (i.e. non-existing) packetNumber is disregarded (no interrupt is generated).

A Move, MoveAndReactivate, Complete, CompleteAndKeepSpace, Extract and Replace on a valid packetNumber with the Active bit de-asserted should not happen (guaranteed by software). If it happens, results are undefined. Only the Insert, Probe, ProbeAndSet and ConditionalActivate operations reply back to the SPU.

If software issues two move-like operations to the PMU that affect the same packet, results are undefined, since there is no guarantee that the moves will happen as software specified.

FIG. 14 is a table showing allowed combinations of Active, Completed, and Probed bits for a valid packet.

Basic Operations

To support the software operations and the monitoring logic, the QS implements the following basic operations:

-   -   1. Enqueue an entry at the tail of a queue.     -   2. Dequeue an entry from the queue in which it resides.     -   3. Move an entry from the head of the queue wherein it currently         resides to the tail of another queue.     -   4. Provide an entry of a queue to the RTU.     -   5. Provide the size of a queue.     -   6. Update any of the fields associated to packetNumber.

Operations 1, 2, 4 and 6 above (applied to different packets at the same time) are completed in 4 cycles in a preferred embodiment of the present invention. This implies a throughput of one operation per cycle.

Some prioritization is necessary when two or more operations could start to be executed at the same time. From highest to lowest priority, these events are inserting from the PMMU, dequeuing an entry, moving an entry from one queue to another queue, sending an entry to the RTU for pre-loading, or a software operation. The prioritization among the software operations is provided by design since software operations are always executed in order.

Early QS Full Detection

The PMU implements a mechanism to aid in flow control between the ASIC (see element 203 in FIG. 2) and the XCaliber processor. Part of this mechanism is to detect that the QS is becoming full and, in this case, a LessThanXpacketIdEntriesInt interrupt is generated to the SPU. The software can enable this interrupt by specifying (in a IntIfLessThanXpacketIdEntries configuration register) a number z larger than 0. An interrupt is generated when 256−y<z, being y the total number of packets currently in process in XCaliber. When z=0, the interrupt will never occur.

Register Transfer Unit (RTU)

A goal of the RTU block is to pre-load an available context with information of packets alive in XCaliber. This information is the packetPage and packetNumber of the packet and some fields of its header. The selected context is owned by the PMU at the time of the pre-loading, and released to the SPU as soon as it has been pre-loaded. Thus, the SPU does not need to perform the costly load operations to load the header information and, therefore, the overall latency of processing packets is reduced.

The RTU receives from the QS a packet identifier (packetPage, packetNumber) and the number of the queue from which the packet comes from) from the QS. This identifier is created partly by the PMMU as a result of a new packet arriving to XCaliber through the network input interface (packetPage), and partly by the QS when the packetPage and device identifier are enqueued (packetNumber).

Another function of the RTU is to execute masked load/store instructions dispatched by the SPU core since the logic to execute a masked load/store instruction is similar to the logic to perform a pre-load. Therefore, the hardware can be shared for both operations. For this reason, the RTU performs either a masked load/store or a pre-load, but not both, at a time, The masked load/store instructions arrive to the RTU through the command queue (CU) block.

Context States

A context can be in one of two states: PMU-owned or SPU-owned. The ownership of a context changes when the current owner releases the context. The PMU releases a context to the SPU in three cases. Firstly, when the RTU has finished pre-loading the information of the packet into the context. Secondly, the PMU releases a context to the SPU when the SPU requests a context to the RTU. In this case, the RTU will release a context if it has one available for releasing. Thirdly, all eight contexts are PMU-owned. Note that a context being pre-loaded is considered to be a PMU-owned context.

The SPU releases a context to the RTU when the SPU dispatches an XStream RELEASE instruction.

Pre-Loading a Context

At boot time, the PMU owns 7 out of the 8 contexts that are available in the embodiment of the invention described in the present example, and the SPU owns one context. The PMU can only pre-load information of a packet to a context that it owns. The process of pre-loading information of a packet into a context is divided into two steps. A first phase to load the address (the offset within the packet memory address space), from where the packet starts. This offset points to the first byte of the two-byte value that codes the size in bytes of the packet. In the case that the packet has been time stamped and HeaderGrowthOffset is not 0, the time stamp value is located at offset−4. The offset address is computed as (packetPage<<8) (HeaderGrowthOffset<<4). This offset is loaded into register number StartLoadingRegister in the selected context. StartLoadingRegister is a boot-time configuration register. The packetNumber value is loaded in register number StartLoadingRegister+1.

The second phase is to load the packet header. The packet header is loaded using registers StartLoadingRegister+2, StartLoadingRegister+3, . . . (as many as needed, and as long as there exist GPR registers). The PatternMatchingTable[q] (q being the queue number associated to the packet) mask specifies how the header of the packet will be loaded into the GPR registers of the context. The PatternMatchingTable is an on-the-fly configuration register that contains masks. To obtain the header data, the RTU requests the SIU to read as many 16-byte lines of packet data as needed into the packet memory. The RTU, upon receiving the 16-byte lines from packet memory (either local or external), selects the desired bytes to load into the context using pattern mask to control this operation.

The step described immediately above of loading the packet header may be disabled by software on a per-queue basis through the on-the-fly PreloadMaskNumber configuration register. This register specifies, for each of the 32 possible queues in the QS, which mask (from 0 to 23) in the PatternMatchingTable is going to be used for the pre-loading. If a value between 24 and 31 is specified in the configuration register, it is interpreted by the RTU as not to perform.

The RTU only loads the GPR registers of a context. The required CP0 registers are initialized by the SPU. Since the context loaded is a PMU-owned context, the RTU has all the available write ports to that context (4 in this embodiment) to perform the loading.

Whenever the pre-loading operation starts, the RTU notifies this event to the SPU through a dedicated interface. Similarly, when the pre-loading operation is completed, the RTU also notified the SPU. Thus the SPU expects two notifications (start and end) for each packet pre-load. A special notification is provided to the SPU when the RTU starts and ends a pre-load in the same cycle (which occurs when the step of loading packet header is disabled). In all three cases, the RTU provides the context number and the contents of the CodeEntryPoint configuration register associated to the packet. In the case that the PMU releases a context to the SPU because all eight contexts are PMU-owned, the contents of the CodeEntryPointSpecial are provided to the SPU. The RTU has an 8-entry table (one for each context), each entry having a packet identifier ready to be pre-loaded and a valid bit that validates the entry. The RTU selects always the valid identifier of the highest entry index to do the pre-load. When a context is associated to this identifier, the corresponding valid bit is de-asserted. The RTU pre-loads one context at a time. After loading a context, the context is released to the SPU and becomes a SPU-owned context. At this point the RTU searches its table for the next packet to be pre-loaded into a context (in case there is at leas one PMU-owned context).

Pattern-Matching Table

FIG. 15 illustrates a Pattern Matching Table which is an on-the-fly configuration register that contains a set of sub-masks. The RTU can use any sub-mask (from 0 to 23) within this table for a pre-loading a context. Sub-masks can also be grouped into a larger mask containing two or more submasks.

FIG. 16 illustrates the format of a mask. A mask is a variable number (1 to 8) of sub-masks of 32×2 bits each, as shown. Every sub-mask has an associated bit (EndOfMask) that indicates whether the composite mask finishes with the corresponding sub-mask, or it continues with the next sub-mask. The maximum total number of sub-masks is 32, out of which 24 (sub-mask indexes 0 to 23) are global, which means any stream in the SPU can use and update them, and 8 are per-stream sub-masks. The per-stream sub-masks do not have an EndOfMask bit, which is because no grouping of per-stream sub-masks is allowed.

The two 32-bit vectors in each sub-mask are named SelectVector and RegisterVector. The SelectVector indicates which bytes from the header of the packet will be stored into the context. The RegisterVector indicates when to switch to the next consecutive register within the context to keep storing the selected bytes by the SelectVector The bytes are always right aligned in the register.

FIG. 17 shows an example of a pre-load operation using the mask in FIG. 16. A bit asserted in the SelectVector indicates that the corresponding byte of the header are stored into a register. In the example, bytes 0, 1 and 7 of the header are loaded into GPR number StartLoadingRegister+2 in bytes 0, 1 and 2, respectively (i.e. the header bytes are right-aligned when loaded into the register). A bit asserted in the RegisterVector indicates that no more header bytes are loaded into the current GPR register, and that the next header bytes, if any, are loaded into the next (consecutively) GPR register. In the example, bytes 12 and 13 of the header are loaded into GPR number StartLoadingRegister+3.

Selecting a PMU-Owned Context

There are a total of eight functional units in the PMU core. However, due to complexity-performance tradeoffs, a stream (context) can only issue instructions to a fixed set of 4 functional units.

The RTU may own at any given time several contexts. Therefore, logic is provided to select one of the contexts when a pre-load is performed, or when a context has to be provided to the SPU. This logic is defined based on how the different streams (contexts) in the PMU core can potentially dispatch instructions to the different functional units, and the goal of the logic is to balance operations that the functional units in the SPU can potentially receive.

The selection logic takes as inputs eight bits, one per context, that indicates whether that context is PMU or SPU-owned. The logic outputs which PMU-owned context(s) that can be selected. 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,3,20,5,6,7,24,9,10,11,12, 13,14,15,32,33,34,3,36,5,6,7,40,9,10,11,12,13,14,15,48,48,48,51,48,53, 54,7,48,57,58,11,60,13,14,15,64,65,66,3,68,5,6,7,72,9,10,11,12,13,14, 15,80,80,80,83,80,85,86,7,80,89,90,11,92,13,14,15,96,96,96,99,96,101, 102,7,96,105,106,11,108,13,14,15,112,112,112,112,112,112,112,119,112, 112,112,123,112,125,126,15,128,129,130,3,132,5,6,7,136,9,10,11,12,13, 14,15,144,144,144,147,144,149,150,7,144,153,154,11,156,13,14,15,160, 160,160,163,160,165,166,7,160,169,170,11,172,13,14,15,176,176,176,176, 176,176,176,183,176,176,176,187,176,189,190,15,192,192,192,195,192,197,198,7,192,201, 202,11,204,13,14,15,208,208,208,208,208,208,208,215,208, 208,208,219,208,221,222,15,224,224,224,224,224,224,224,231,224,224,224,235,224,237,2 38,15,240,240,240,240,240,240,240,240,240,240,240,240,240,240,240

The selection logic is specified with the previous list of 254 numbers. Each number is associated to a possible combination of SPU/PMU-owned context. For example, the first number corresponds to the combination ‘00000001’, i.e. context number 0 is PMU owned and context numbers 1 to 7 are SPU owned (LSB digit corresponds to context 0, MSB digit to context 7; digit value of 0 means SPU owned, digit value of 1 means PMU owned). The second number corresponds to combination ‘00000010’, the third to combination ‘00000011’, and so forth up to combination ‘11111110’. The 19^(th) combination (‘00010011’) has associated number 3 (or ‘00000011’) in the previous list, which means that context 0 and 1 can be selected. Context 4 could also be selected, however it is not the best choice to balance the use of the functional units in the SPU core.

Interrupt when No Context is Available

The RTU has a table of 8 entries named NewPacketIdTable). Entry p in this table contains a packet identifier (packetPage, packetNumber and queue number) with an RTU-priority of p, and a Valid bit that validates the identifier. When the RTU is not busy pre-loading or executing a masked load/store, it will obtain from this table the valid identifier with the highest RTU-priority. In case it exists and there is at least one PMU-owned context, the RTU will start the pre-loading of a PMU-owned context, and it will reset the Valid bit in the table.

In case there is no PMU-owned context, the RTU sits idle (assuming no software operation is pending) until a context is released by the SPU. At that point in time the RTU obtains, again, the highest valid RTU-priority identifier from the NewPacketIdTable (since a new identifier with higher RTU priority could have been sent by the QS while the RTU was waiting for a context to be released by the SPU). The Valid bit is reset and the packet information starts being pre-loaded into the available context. At this point the RTU is able to accept a packet with RTU priority p from the QS.

When an identifier with a RTU priority of p is sent by the QS to the RTU, it is loaded in entry p in the NewPacketIdTable, and the Valid bit is set. At this time, if the number of valid identifiers (without counting the incoming one) in the NewPacketIdTable is equal or larger than the current available PMU-owned contexts (without counting the context that the RTU currently might be loading), then a PacketAvailableButNoContextPriorityP Int interrupt is generated to the SPU. P ranges from 0 to 7, and its value is determined by a boot-time configuration flag PacketAvailableButNo ContextIntMapping. If this flag is ‘0’, P is determined by the 3-bit boot-time configuration register DefaultPacketPriority. If this flag is ‘I’, P is the RTU priority. However, the PacketAvailableButNoContextPriorityPint will not be generated if the corresponding configuration flag PacketAvailableButNo ContextPriorityPintEnable is de-asserted.

The SPU, upon receiving the interrupt, decides whether or not to release a context that it owns so that the RTU can pre-load the packetPage, packetNumber and header information of the new packet.

When the RTU generates a PacketAvailableButNoContext PriorityPInt interrupt, it may receive after a few cycles a context that has been released by the SPU. This context, however, could have been released when, for example, one of the streams finished the processing of a packet. This can happen before the interrupt service routine for the PacketAvailable ButNoContextPriorityPInt interrupt finishes. Thus, when a context is released due to the ISR completion, the packet pre-load that originated the interrupt already might have used the context first released by another stream in the SPU. Thus, the context released due to the interrupt will be used for another (maybe future) packet pre-load. If no other entry is valid in the NewPacketIdTable, the context is be used and sits still until either an identifier arrives to the RTU or the SPU requesting a context to the RTU.

Whenever a context becomes SPU-owned, and the RTU has a pre-load pending, the RTU selects the most priority pending pre-load (which corresponds to the highest-valid entry in the NewPacketTable), and will start the preload. If the PacketAvailableButNoContextPriorityint interrupt associated to this level was asserted, it gets de-asserted when the pre-load starts.

Software Operations on the RTU

Software executes a number of instructions that affect the RTU. Following is a list of all operations that can be generated to the RTU as a result of dispatch by the SPU core of an XStream packet instruction. The operations arrive to the RTU through the command queue (CU), along with the context number associated to the stream that issued the instruction:

1. Release(c): context number c becomes PMU owned.

2. GetContext: the RTU returns the number of a PMU-owned context number. This context, if it exists, becomes SPU owned and a success flag is returned asserted; otherwise it is return de-asserted, in which case the context number is meaningless.

3. MaskedLoad(r,a,m), MaskedStore(r,a,m): the SPU core uses the RTU as a special functional unit to execute the masked load/store instructions since the logic to execute a masked load/store instruction is similar to the logic to perform a pre-load. Therefore, the hardware can be shared for both operations. For this reason, the RTU performs either a masked load/store or a pre-load, but not both at a time. For either the masked load or masked store, the RTU will receive the following parameters:

-   -   (a) A mask number m that corresponds to the index of the first         submask in the PatternMatchingTable to be used by the masked         load/store operation.     -   (b) A 36-bit address a that points to the first byte in (any)         memory to which the mask will start to be applied.     -   (c) A register number r (within the context number provided)         that corresponds to the first register involved in the masked         load/store operation. Subsequent registers within the same         context number will be used according to the selected mask.

For masked load/store operations, the mask can start to be applied at any byte of the memory, whereas in a pre-load operation (a masked-load like operation) the mask will always be applied starting at a 16-byte boundary address since packet data coming from the network input interface is always stored in packet memory starting at the LSB byte in a 16-byte line.

The MaskedLoad, MaskedStore and GetContext operations communicate to the SPU when they complete through a dedicated interface between the RTU and the SPU. The RTU gives more priority to a software operation than packet pre-loads. Pre-loads access the packet memory whereas the masked load/store may access any memory in the system as long as it is not cacheable or write-through. If not, results are undefined.

The RTU is able to execute a GetContext or Release command while executing a previous masked load/store command.

Programming Model

Software can configure, either at boot time or on the fly, several of the features of the PMU. All of the features configurable at boot time only, and some configurable on the fly, must happen only when the SPU is running in a single-stream mode. If not, results are undefined. The PMU does not check in which mode the SPU is running.

Software can update some of the information that the PMU maintains for a given packet, and also obtain this information. This is accomplished by software through new XStream packet instructions that are the subject of separate patent applications. These instructions create operations of three different types (depending on which block of the PMU the operation affects, whether PMMU, QS or RTU) that will be executed by the PMU. Some of the operations require a result from the PMU to be sent back to the SPU.

The packet memory and configuration space are memory mapped. The SIU maintains a configuration register (16 MB aligned) with the base address of the packet memory, and a second configuration register with the base address of EPM. Software sees the packet memory as a contiguous space. The system, however, allows the EPM portion of the packet memory to be mapped in a different space.

The SIU also maintains a third configuration register with the base of the PMU configuration register space. All the load/store accesses to LPM and configuration space performed by the SPU reach the PMU through the SIU. The SIU determines to which space the access belongs, and lets the PMU know whether the access is to LPM or to the PMU configuration space. Accesses to the EPM are transparent to the PMU.

The PMU can interrupt the SPU when certain events happen. Software can disable all these interrupts through configuration registers.

Configuration Registers

The configuration registers of the PMU reside in the PMU Configuration Space of the XCaliber address space. The base address of this space is maintained by the SIU and does not need to be visible by the PMU. The SIU notifies to the PMU with a signal when a read/write access performed by the SPU belongs to this space, along with the information needed to update the particular register on a write access.

Some of the PMU configuration registers can be configured only at boot time, and some can be configured on the fly. All boot-time configurable and some on-the-fly configurable registers need to be accessed in single-stream mode. A boot-time configurable register should only be updated if the PMU is in reset mode. Results are undefined otherwise. The PMU will not check whether the SPU is indeed in single-stream mode when a single-stream mode configuration register is updated. All the configuration registers come up with a default value after the reset sequence.

In the instant embodiment 4 KB of the XCaliber address space is allocated for the PMU configuration space. In XCaliber's PMU, some of these configuration registers are either not used or are sparsely used (i.e. only some bits of the 32-bit configuration register word are meaningful).

The non-defined bits in the PMU configuration space are reserved for future PMU generations. Software can read or write these reserved bits but their contents, although fully deterministic, are undefined.

FIG. 18 shows the PMU Configuration Space, which is logically divided into 32-bit words. Each word or set of words contains a configuration register.

FIGS. 19 a and 19 b are two parts of a table showing mapping of the different PMU configuration registers into the different words of the configuration space. The block owner of each configuration register is also shown in the table.

Following is the list of all configuration registers in this particular embodiment along with a description and the default value (after PMU reset). For each of the configuration registers, the bit width is shown in parenthesis. Unless otherwise specified, the value of the configuration register is right aligned into the corresponding word within the configuration space.

Boot-Time Only Configuration Registers:

1. Log2InputQueues (5)

-   -   (a) Default Value: 0     -   (b) Description: Number of queues in the QS used as input queues         (i.e. number of queues in which packetPages/deviceIds from the         PMMU will be inserted).         2. PriorityClustering (3)     -   (a) Default Value: 5 (32 clusters)     -   (b) Description: Specifies how the different queues in the QS         are grouped in priority clusters (0: 1 cluster, 1: 2 clusters,         2: 4 clusters, . . . 5: 32 clusters).         3. HeaderGrowthOffset (4)     -   (a) Default Value: 0     -   (b) Description: Number of empty 16-byte chunks that will be         left in front of the packet when it is stored in packet memory.         Maximum value is 15 16-byte chunks. Minimum is 0.         4. TailGrowthOffset (6)     -   (a) Default Value: 0     -   (b) Description: Number of empty 16-byte chunks that will be         left at the end of the packet when it is stored in packet         memory. Maximum value is 63 16-byte chunks. Minimum is 0.         5. PacketAvailableButNoContextIntMapping (1)     -   (a) Default Value: 0     -   (b) Description: Specifies the P in the         PacketAvailableButNoContextPriorityPInt interrupt, if enabled.         The possible values are:         -   (1) 0: P is specified by the DefaultPacketPriority register.         -   (2) 1: P is the RTU priority.             6. StartLoadingRegister (5)     -   (a) Default Value: 1     -   (b) Description: Determines the first GPR register number to be         loaded by the RTU when performing the background load of the         packet header on the chosen context. In this register, the value         (packetPage<<8)|(HeaderGrowthOffset<<4) is loaded. The         packetNumber is loaded in the next GPR register. The following         GPR registers will be used to pre-load the packet header data         following PatternMatchingMask0 mask if this feature is enabled.         7. PreloadMaskNumber (32×5)     -   (a) Default Value: mask 31 for all queues (i.e. pre-load of         header is >disabled).     -   (b) Description: It specifies, for each of the 32 possible         queues in the QS, which mask in the PatternMatchingTable is         going to be used for pre-loading.

FIGS. 19 a-c show a mapping of the PreloadMaskNumber configuration register.

The configuration registers described above are the boot-time-only configuration registers in the instant example. Immediately below are listed the On-The-Fly configuration registers.

Single-Stream Configuration Registers

1. OverflowEnable (1)

-   -   (a) Default Value: 0     -   (b) Description: Enables/disables the overflow of packets in         case they do not fit into LPM. When disabled, these packets are         dropped.         2. PatternMatchingTable (24×(32×2+1)     -   (a) Default Value (per each of the 24 entries):         -   (1) SelectVector: select all bytes         -   (2) RegisterVector: store 4 consecutive bytes per register         -   (3) EndOfMask: 1     -   (b) Description: It specifies, for masked load/store operations,         which bytes to load/store and in which (consecutive) registers.         Mask 0 of this table is used by the RTU to pre-load, in the         background, some bytes of the header of the packet in one of the         available contexts. There are a total of 24 masks.     -   (c) Note: Mask 0 needs to be written when the PMU is freezed         (see Section 0), otherwise results are undefined.

FIG. 21 illustrates the PatternMatchingTable described immediately above.

3. Freeze (1)

-   -   (a) Default Value: 1     -   (b) Description: Enables/disables the freeze mode.         4. Reset (1)     -   (a) Default Value: 0     -   (b) Description: When set to 1, forces the PMU to perform the         reset sequence. All packet data in the PMU will be lost. After         the reset sequence all the configuration registers will have the         default values.         Multi-stream Configuration Registers         1. ClearErrorD (D=0,1)     -   (a) Default Value: 0     -   (b) Description: When written by software (with any data), the         packet error condition detected on device identifier D is         cleared.         2. PacketAvailableButNoContextPriorityPintEnable (8) [P=0 . . .         7]     -   (a) Default Value: 0 (for all levels)     -   (b) Description: Enables/disables the         PacketAvailableButNoContextPriorityPint interrupt.         3. AutomaticPacketDropIntEnable (1)     -   (a) Default Value: 1     -   (b) Description: Enables/disables the AutomaticPacketDropInt         interrupt.         4. TimeStampEnable (1)     -   (a) Default Value: 0     -   (b) Description: Enables/disables the time stamp of packets.         When enabled and HeaderGrowthOffset is greater than 0, a 4-byte         time stamp is appended to the packet before it is written into         the packet memory.         5. PacketErrorIntEnable (1)     -   (a) Default Value: 0     -   (b) Description: Enables/disables the PacketErrorInt interrupt.         6. VirtualPageEnable (9×4)     -   (a) Default Value: all virtual pages enabled for all blocks.     -   (b) Description: Enables/disables the virtual pages for each of         the 4 blocks that the LPM is divided into. There are up to 9         virtual pages, from 256 bytes (enabled by the LSB bit) up to 64         K bytes (enabled by the MSB bit), with all power-of-two sizes in         between.

FIG. 22 illustrates the VirtualPageEnable register.

7. OverflowAddress (24)

-   -   (a) Default Value: 0x40000 (the first atomic page in the EPM)     -   (b) Description: the 16 MSB bits correspond to the atomic page         number in packet memory into which the packet that is overflowed         will start to be stored. The 8 LSB are hardwired to ‘0’ (i.e.         any value set by software to these bits will be disregarded).         OverflowAddress is then the offset address within the 16 MB         packet memory. The SIU will translate this offset into the         corresponding physical address into the EPM. The first 1K atomic         pages of the packet memory correspond to the LPM. If software         sets the 16 MSB of OverflowAddress to 0.1023, results are         undefined. When a packet is overflowed, the 16 MSB bits of         OverflowAddress become the packetPage for that packet. The SPU         allows the next packet overflow when it writes into this         configuration register.         8. IntIfNoMoreXsizePages (4)     -   (a) Default Value: 0xF (i.e. the interrupt will never be         generated)     -   (b) Description: Specifies the index of a virtual page (0:256         bytes, 1:512 bytes, . . . , 8:64K bytes, 9-15: no virtual page).         Whenever the PMMU detects that there are no more virtual pages         of that size in all the LPM, the NoMoreThanXSizePagesInt         interrupt will be generated to the SPU.         9. IntIfLessThanXpacketIdEntries (9)     -   (a) Default Value: 0     -   (b) Description: Minimum number of entries in the QS available         for new packet identifiers. If the actual number of available         entries is less than this number, an interrupt will be generated         to the SPU. If this number is 0, the LessThanXPacketIdEntriesInt         interrupt will not be generated.         10. DefaultPacketPriority (3)     -   (a) Default Value: 0     -   (b) Description: Provides the priority level for the         PacketAvailableButNoContextInt interrupt when         PacketAvailableButNoContextMapping is 0.         11. ContextSpecificPatternMatchingMask: (8×(32×2))     -   (a) Default Value:         -   (1) SelectVector: select all bytes         -   (2) RegisterVector: store 4 bytes in each register             (EndOfMask is hardwired to 1)     -   (b) Description: It specifies, for masked load/store operations,         which bytes to load/store and in which (consecutive) registers.         Software will guarantee that a stream only access its         corresponding context-specific mask.

FIG. 23 illustrates the ContextSpecificPAtternMAtching mask configuration register.

12. FirstInputQueue (5)

-   -   (a) Default Value: 0     -   (b) Description: Specifies the smallest number of the queue into         which packets from the PMMU will be inserted.         13. SoftwareOwned (4)     -   (a) Default Value: 0 (not software owned)     -   (b) Description: one bit per LPM block. If ‘1’, the block is         software owned, which implies that the memory of the block is         managed by software, and that the VirtualPageEnable bits for         that block are a don't care.         14. MaxActivePackets (32×9)     -   (a) Default Value: 256 for each of the queues.     -   (b) Description: Specifies, for each queue q, a value between 0         and 256 that corresponds to the maximum number of packets within         queue q that can be being processed by the SPU.

FIG. 24 illustrates the MaxActivePackets configuration register.

15. CodeEntryPoint (32×30)

-   -   (a) Default Value: 0 for each of the queues.     -   (b) Description: The contents of the CodeEntryPoint register         associated to queue q are sent to the SPU when a context is         activated which has been pre-loaded with a packet that resides         in queue q.         16. CodeEntryPointSpecial (30)     -   (a) Default Value: 0     -   (b) Description: The contents of this register are sent to the         SPU when a context is activated due to the fact that all the         contexts become PMU-owned.         17. Bypass Hooks (9)     -   (a) Default Value: 0     -   (b) Description: See FIG. 32. Each bit activates one hardware         bypass hook. The bypass hook is applied for as many cycles as         the corresponding bit in this register is asserted.         18. InternalStateWrite (12)     -   (a) Default Value: 0     -   (b) Description: See FIG. 33. Specifies one word of internal PMU         state. The word of internal state will be available to software         when reading the InternalStateRead configuration register. The         InternalStateWrite configuration register is only used in one         embodiment to debug the PMU.         Read-Only Registers         1. SizeOfOverflowedPacket (16)     -   (a) Default Value: 0     -   (b) Description: Whenever the PMU has to overflow a packet, this         register will contain the size in bytes of that packet.         2. TimeCounter (64)     -   (a) Default Value: 0     -   (b) Description: Contains the number of core clock cycles since         the last reset of the PMU.

The TimeCounter configuration register is illustrated in FIG. 25.

3. StatusRegister (8)

-   -   (a) Default Value: 1     -   (b) Description: Contains the state of the PMU. This register is         polled by the SPU to figure out when the reset or freeze has         completed (Freeze and Reset bits), or to figure out the source         of packet error per inbound device identifier (Err: 1-error,         0-no error; EPM: 1-error has occurred while packet is overflowed         to EPM, 0-error has occurred while packet is being stored in         LPM; PSM: 1-error due to a packet size mismatch, 0-error due to         a bus error).

FIG. 26 illustrates the StatusRegister configuration register

Interrupts

The PMU can interrupt the SPU when certain events happen. Software can disable all these interrupts using some of the configuration registers listed above. Moreover, each stream can individually mask these interrupts, which is the subject of a separate patent application. The list of interrupts that the PMU generate are as follows:

1. OverflowStartedInt

-   -   (a) Interrupt Condition: When the PMMU cannot store the incoming         packet into the LocalPacketMemory, it will overflow the packet         to the ExternalPacketMemory through the SIU.     -   (b) Disable Condition: OverflowEnable=‘0’         2. NoMorePagesOfXSizeInt     -   (a) Interrupt Condition: When no more free virtual pages of the         size indicated in IntIfNoMoreXSizePages are available.     -   (b) Disable Condition: IntIfNoMoreXSizePages={10, 11, 12, 13,         14, 15}.         3. LessThanXPacketIdEntriesInt     -   (a) Interrupt Condition: When the actual number of available         entries in the QS is less than IntIfLessThanXPacketIdEntries.     -   (b) Disable Condition: IntIfLessThanXPacketIdEntries=0         4. PacketAvailableButNoContextPriorityPint (P=0.7)     -   (a) Interrupt Condition: When a packet identifier is received by         the RTU from the QS but there is no available context.     -   (b) Disable Condition:         PacketAvailableButNoContextPriorityPIntEnable=0         5. AutomaticPacketDropInt     -   (a) Interrupt Condition: When a packet cannot be stored in LPM         and OverflowEnable=‘0’.     -   (b) Disable Condition: AutomaticPacketDropIntEnable=‘0’         6. PacketErrorInt     -   (a) Interrupt Condition: When the actual size of the packet         received from the ASIC does not match the value in the first two         bytes of the ASIC-specific header, or when a bus error has         occurred.     -   (b) Disable Condition: PacketErrorIntEnable=‘0’

Interrupts to the SPU in this embodiment are edge-triggered, which means that the condition that caused the interrupt is cleared in hardware when the interrupt is serviced. This also implies that the condition that causes the interrupt may happen several times before the interrupt is served by the SPU. Therefore, the corresponding interrupt service routine will be executed only once, even though the condition that causes the interrupt has happened more than once.

This behavior is not desirable for some of the interrupts. For these cases, a special interlock mechanism is implemented in hardware that guarantees that the condition will not happen again until the interrupt has been serviced.

An example of the special interlock mechanism is the case of the OverflowStartedInt and PacketAvailableButNoContextPriorityPInt interrupts. In the first case, when a packet is overflowed, no other packet are overflowed until the software writes a new address in the on-the-fly configuration register OverflowAddress. If a packet has been overflowed but the OverflowAddress register still has not been written by the software, any subsequent packet that would have otherwise been overflowed because it does not fit in the LPM must be dropped.

For the 8 PacketAvailableButNoContextPriorityPInt (P=0.7) interrupts, the PMU architecture implicitly guarantees that no multiple conditions (per each P) will occur. This is guaranteed by design since:

-   -   (a) the PacketAvailableButNoContextPriorityPInt interrupt is         only generated when a packet identifier of RTU priority P         arrives to the RTU, and     -   (b) at most, only one packet identifier with RTU priority P         resides in the RTU.

The other interrupts can suffer from the multiple condition effect. Therefore, software should not rely on counting the number of times a given type of interrupt happens to figure out exactly how many times that condition has occurred.

Protection Issues

The architecture of the PMU in the instant embodiment creates the following protection issues:

1. An stream could read/write data from a packet other than the one it is processing. An stream has access to all the packet memory, and there is no mechanism to prevent an stream from accessing data from a totally unrelated packet unless the packet memory is mapped as kernel space.

2. Since the configuration registers are memory mapped, any stream could update a configuration register, no matter whether the SPU is in single-stream mode or not. In particular, any stream could freeze and reset the PMU.

3. Whenever a packet is completed or moved with reactivation, nothing prevents software from continuing “processing” the packet.

Command Unit (CU)

Software can update some information that the PMU maintains for a given packet and obtain this information. This is accomplished by software through some of the new XStream packet instructions referred to above. Some of these instructions are load-like in the sense that a response is required from the PMU. Others are store-like instructions, and no response is required from the PMU.

FIG. 27 is a diagram of Command Unit 213 of FIG. 2, in relation to other blocks of the XCaliber processor in this example, all of which bear the same element numbers in FIG. 27 as in FIG. 2. The SPU dispatches, at most, two packet instructions per cycle across all contexts (one instruction per cluster of the SPU). The type of the packet instruction corresponds to the PMU block to which the instruction affects (PMMU, QS or RTU). When the SPU dispatches a packet instruction, a single command to the PMU is generated and inserted into one of three different queues in the CU block (one queue per PMU block to which the command goes). Commands to the PMU are issued to PMMU command queue 2703, those to the QS go to QS command queue 2705, and command to the RTU go to the RTU command queue 2707. Each queue can hold up to 8 commands. The SPU only dispatches a command to the CU if there are enough free entries in the corresponding queue.

The CU is responsible for dispatching the commands to the respective blocks, and gathering the responses (if any) in an 8-entry ResponseQueue 2709, which queues responses to be returned to the SPU. The CU can receive up to three responses in a given cycle (one from each of the three blocks). Since (a) only one outstanding packet instruction is allowed per stream, (b) the Response Queue has as many entries as streams, (c) only one command to the PMU is generated per packet instruction, and (d) only one response is generated per each load-like command, it is guaranteed that there will be enough space in the ResponseQueue to enqueue the responses generated by the PMU blocks. The ResponseQueue should be able to enqueue up to two commands at a time.

CU 213 also receives requests from SIU 107 to update the configuration registers. These commands are also sent to the PMMU, RTU and QS blocks as commands. The PMMU, QS, and RTU keep a local copy of the configuration registers that apply to them. The CU keeps a copy as well of all the configuration registers, and this copy is used to satisfy the configuration register reads from the SIU.

For read-only configuration registers, a special interface is provided between the CU and the particular unit that owns the read-only configuration register. In XCaliber's PMU, there exists two read-only configuration registers: one in the PMMU block (SizeOfOverflowedPacket) and the other one in the CU block (StatusRegister). Whenever the PMMU writes into the SizeOfOverflowedPacket register, it notifies the CU and the CU updates its local copy.

Commands in different queues are independent and can be executed out of order by the PMU. Within a queue, however, commands are executed in order, and one at a time. The PMU can initiate the execution of up to 3 commands per cycle. The PMMU and QS blocks give more priority to other events (like the creation of a new packetPage when a new packet arrives -PMMU-, or the extraction of a packet identifier because it needs to be sent out -QS-) than to the commands from the SPU. This means that a command that requests some data to be sent back to the SPU may take several cycles to execute because either the PMMU or QS might be busy executing other operations.

RTU 227 has two sources of commands: from the QS (to pre-load packet information into an available context) and from the SPU (software command). The RTU always gives more priority to SPU commands. However, the RTU finishes the on-going context pre-load operation before executing the pending SPU command.

Command/Response Formats

A command received by the CMU has three fields in the current embodiment:

1. Context number, which is the context associated to the stream that generated the command.

2. Command opcode, which is a number that specifies the type of command to be executed by the PMU.

3. Command data, which is the different information needed by the PMU to execute the command specified in the command opcode field.

The PMU, upon receiving a command, determines to which of the command queues the command needs to be inserted. A command inserted in any of the queues has a similar structure as the command received, but the bit width of the opcode and the data will vary depending on the queue. The table of FIG. 28 shows the format of the command inserted in each of the queues. Not included are the Read Configuration Register and Write Configuration Register commands that the CU sends to the PMMU, QS and RTU blocks.

Each command that requires a response is tagged with a number that corresponds to the context associated to the stream that generated the command. The response that is generated is also tagged with the same context number so that the SPU knows to which of the commands issued it belongs.

As described above, there is only one ResponseQueue 2709 (FIG. 27) that buffers responses from the three PMU blocks. Note that there is no need to indicate from which block the response comes since, at most, one packet instruction that requires a response will be outstanding per stream. Therefore, the context number associated to a response is enough information to associate a response to a stream.

FIG. 29 is a table showing the format for the responses that the different blocks generate back to the CU. Not included in the table are the configuration register values provided by each of the blocks to the CU when CU performs a configuration register read.

The RTU notifies the SPU, through a dedicated interface that bypasses the CU (path 2711 in FIG. 27), of the following events:

1. A masked load/store operation has finished. The interface provides the context number.

2. A GetContext has completed. The context number associated to the stream that dispatched the GetContext operation, and the context number selected by the RTU is provided by the interface. A success bit is asserted when the GetContext succeeded; otherwise it is de-asserted.

3. A pre-load either starts or ends. The context number and the priority associated to the packet is provided to the SPU.

Reset and Freeze Modes

The PMU can enter the reset mode in two cases:

1. SPU sets the Reset configuration flag.

2. XCaliber is booted.

The PMU can also enter the freeze mode in two cases:

1. SPU sets the Freeze configuration flag.

2. PMU finishes the reset sequence.

The reset sequence of the PMU takes several cycles. During this sequence, the Reset bit in the StatusRegister configuration register is set. After the reset sequence, all the configuration registers are set to their default values, and the PMU enters the freeze mode (the Reset bit in the StatusRegister is reset and the Freeze bit is set). When this is done, the SPU resets the Freeze configuration flag and, from that time on, the PMU runs in the normal mode.

When the SPU sets the Freeze configuration flag, the PMU terminates the current transaction or transactions before setting the Freeze bit in the StatusRegister. Once in the freeze mode, the PMU will not accept any data from the network input interface, send any data out through the network output interface, or pre-load any packet

The PMU continues executing all the SPU commands while in freeze mode.

The SPU needs to poll the StatusRegister configuration register to determine in which mode the PMU happened to be (reset or freeze) and to detect when the PMU changes modes.

The CU block instructs the rest of the blocks to perform the reset and the freeze. The following is the protocol between the CU and any other block when the CU receives a write into the reset and/or freeze configuration bit:

1. The CU notifies to some of the blocks that either a freeze or a reset needs to be performed.

2. Every block performs the freeze or the reset. After completion, the block signals back to the CU that it has completed the freeze or reset.

3. The CU updates the StatusRegister bits as soon as the reset or freeze has been completed. Software polls the StatusRegister to determine when the PMU has completely frozen.

The different blocks in the PMU end the freeze when:

1. IB, LPM, CU and QS do not need to freeze.

2. As soon as the PMMU finishes uploading inbound packets, if any, and downloading outbound packets, if any.

3. As soon as the RTU has finished the current pre-load operation, if any.

4. As soon as the OB is empty.

While in freeze mode, the blocks will not:

1. start uploading a new packet; start downloading a completed packet; or generate interrupts to the SPU (PMMU)

2. pre-load a context or generate interrupts to the SPU (RTU).

If software writes a ‘1’ in the Freeze/Reset configuration register and then writes a ‘0’ before the PMU froze or reset, results are undefined. Once the PMU starts the freeze/reset sequence, it completes it.

Performance Counters Interface

The PMU probes some events in the different units. These probes are sent to the SIU and used by software as performance probes. The SIU has a set of counters used to count some of the events that the PMU sends to the SIU. Software decides which events throughout the XCaliber chip it wants to monitor. Refer to the SIU Architecture Spec document for more information on how software can configure the performance counters.

FIG. 30 shows a performance counter interface between the PMU and the SIU. Up to 64 events can be probed within the PMU. All 64 events are sent every cycle to the SIU (EventVector) through a 64-bit bus. Each of the 64 events may have associated a value (0 to 64K−1). Software selects two of the events (EventA and EventB). For each of these two, the PMU provides the associated 16-bit value (EventDataA and EventDataB, respectively) at the same time the event is provided in the EventVector bus.

Events are level-triggered. Therefore, if the PMU asserts the event for two consecutive cycles, the event will be counted twice. The corresponding signal in the EventVector will be asserted only if the event occurs, and for as many cycles as the event condition holds.

The SIU selects which events are actually counted (based on how software has programmed the SIU). If the SIU decides to count an event number different from EventA or EventB, a counter within the SIU counts the event for as many cycles the corresponding bit in the EventVector is asserted. If the events monitored are EventA and/or EventB, the SIU, in addition to counting the event/s, increments another counter by EventDataA and/or EventDataB every time the event occurs.

FIG. 31 shows a possible implementation of the internal interfaces among the different blocks in PMU 103. CU acts as the interface between the PMU and SIU for the performance counters. CU 213 distributes the information in EventA and EventB to the different units and gathers the individual EventVector, EventDataA and EventDataB of each of the units.

The CU block collects all the events from the different blocks and send them to the SIU. The CU interfaces to the different blocks to notify which of the events within each block need to provide the EventDataA and/or EventDataB values.

Performance events are not time critical, i.e. they do not need to be reported to the SIU in the same cycle they occur.

FIGS. 34 through 39 comprise a table that lists all events related to performance counters. These events are grouped by block in the PMU. The event number is shown in the second column. This number corresponds to the bit in the EventVector that is asserted when the event occurs. The third column is the event name. The fourth column shows the data value associated to the event and its bit width in parentheses. The last column provides a description of the event.

The CU block collects all of the events from the different blocks and sends them to the SIU. The CU interfaces to the different blocks to notify which of the events within each block need to provide the EventDataA and the EventDataB values.

Performance events are not time critical, i.e. they do not need to be reported to the SIU in the same cycle that they occur.

Debug Bypasses and Trigger Events

Hardware debug hooks are implemented in the PMU to help debugging of the silicon. The debug hooks are divided into two categories:

1. Bypass hooks: will bypass potentially faulty functions. Instead of the faulty results generated by these functions (or, in some cases, no result at all), the bypass hook will provide at least some functionality that will allow other neighboring blocks to be tested.

2. Trigger events: when a particular condition occurs in the PMU (trigger event), the PMU will enter automatically in single-step mode until, through the OCI Interface (Section), the SIU sends a command to the PMU to exit the single-step mode.

Moreover, the PMU has the capability of being single-stepped. A signal (SingleStep) will come from the OCI Interface. On a cycle-by-cycle basis, the different blocks of the PMU will monitor this signal. When this signal is de-asserted, the PMU will function normally. When SingleStep is asserted, the PMU will not perform any work: any operation on progress will be held until the signal is de-asserted. In other words, the PMU will not do anything when the signal is asserted. The only exception to this is when a block can lose data (an example could be in the interface between two block: a block A sends data to a block B and assumes that block B will get the data in the next cycle; if SingleStep is asserted in this cycle, block B has to guarantee that the data from A is not lost).

Bypass Hooks

The different bypass hooks in the PMU are activated through the on-the-fly BypassHooks configuration register. FIG. 40 is a table illustrating the different bypass hooks implemented in the PMU. The number of each hook corresponds to the bit number in the BypassHooks register The bypass hook is applied for as many cycles as the corresponding bit in this register is asserted.

Trigger Events

The following is a list of trigger events implemented in the PMU.

1. A new packet of size s bytes is at the head of the IBU.

-   -   (a) s=0: any packet.         2. A packetId from source s with packetPage pp is inserted in         queue q in the QS.     -   (a) s=0: PMM, S=1: QS, s=2: CMU; s=3: any     -   (b) pp=0x10000: any     -   (c) q=33: any         3. A packetId from queue q with packetPage pp and packetNumbet         pn is sent to RTU.     -   (a) pp=0x10000: any     -   (b) q=33: any     -   (c) pn=256: any         4. A packetId with packetPage pp and packetNumber pn reaches the         head of queue q in the QS.     -   (a) pp=0x10000: any     -   (b) q=33: any     -   (c) pn=256: any         5. A packet with RTU priority p and packetPage pp and         packetNumber pn is pre-loaded in context c.     -   (a) pp=0x10000: any     -   (b) q=33: any     -   (c) pn=256: any     -   (d) c=8: any         6. A packetId from queue q with packetPage pp and packetNumber         pn is sent for downloading to PMM.     -   (a) pp=0x10000: any     -   (b) q=33: any     -   (c) pn=256: any         7. A packetId with packetPage pp and packetNumber pn reaches the         head of queue q in the QS.     -   (a) pp=0x10000: any     -   (b) q=33: any     -   (c) pn=256: any         8. Packet command pc is executed by block b.     -   (a) pc=0: GetSpace; pc=1: FreeSpace; pc=2: InsertPacket; pc=3:         ProbePacket; pc=4: ExtractPacket; pc=5: CompletePacket; pc=6:         UpdatePacket; pc=7: MovePacket; pc=8: ProbeQueue; pc=9:         GetContext; pc=10: ReleaseContext; pc=11: MaskedLoad; pc=12:         MaskedStore; pc=13: any     -   (b) b=0: RTU; b=1: PMM; b=2: QS; b=3: any         Detailed Interfaces with the SPU and SIU

The architecture explained in the previous sections is implemented in the hardware blocks shown in FIG. 41:

SPU-PMU Interface

FIGS. 42-45 describe the SPU-PMU Interface.

SPU-PMU Interface

FIGS. 46-49 describe the SIU-PMU Interface.

The specification above describes in enabling detail a Packet Memory Unit (PMU) for a Multi-Streaming processor adapted for packet handling and processing. Details of architecture, hardware, software, and operation are provided in exemplary embodiments. It will be apparent to the skilled artisan that the embodiments described may vary considerably in detail without departing from the spirit and scope of the invention. It is well-known, for example, that IC hardware, firmware and software may be accomplished in a variety of ways while still adhering to the novel architecture and functionality taught.

Functional Validation of a Packet Manager

In one aspect of the present invention, the inventor provides a system and method for validating the function of a packet managing unit (PMU) in a processor system. In a preferred embodiment the processor system is a multi-streaming processor

FIG. 50 is a block diagram illustrating main components of a dynamic multi-streaming processor, termed the XCaliber processor in a specific example in this specification. It should be remembered, however, that this is a simple example, not a limitation. The invention is not limited to interaction with a dynamic multistreaming processor. The architecture is according to an embodiment of the present invention. In this example, there are several main components of the multi-streaming processor illustrated. A packet management unit (PMU) 5001, and a streaming processor unit (SPU) 5002 are illustrated in logical coordination with a system interface unit (SIU) 5000. It has been previously described that the PMU and the SPU communicate in some aspects (memory accesses) chiefly through the SIU, and directly in some other aspects (packet instructions). The SIU also serves as an interface to a network interface 5004, a memory interface 5005, and a system interface 5006.

Contexts 5003 are illustrated logically in this example between PMU 5001 and SPU 5002. In actual practice, contexts 5003 are implemented within the SPU core. It has been described above with reference to Ser. No. 09/737,375 that a context or contexts 5003 may either be PMU-owned or SPU-owned. When a context is being preloaded with packet information for processing it is considered to be PMU owned. When a context is about to be released by PMU 5001 notification is sent to SPU 5002 whereupon SPU 5002 pre-fetches instructions for processing information within the released context, which is now considered to be SPU owned through the duration of processing. After packet processing is complete, SPU 5002 releases the context back to PMU 5001. Bi-directional arrows illustrated between PMU 5001 and context's 5003 as well as between contexts 5003 and SPU 5000 illustrate this ongoing relationship between the two components.

Packet commands generated by SPU 5002 are communicated to PMU 5001 through a command unit (CU) described with reference to Ser. No. 09/737,375 FIG. 1 under the heading Overview of the PMU. A simple bi-directional arrow labeled Packet Commands serves to illustrate the coordination of SPU/PMU command propagation through a command unit.

Network interface 5004 represents ingress and egress circuitry between the routing system and the operating network. Memory interface 5005 represents a path to external system memory, and system interface 5006 represents all interface capability with other remote components of a packet routing system using DMS technology as described with regard to disclosure of Ser. No. 09/737,375 referenced herein.

As previously described, a primary function of PMU 5001 is to offload packet management responsibility that would otherwise be provided by SPU 5002, in order to create a more efficient processing environment. PMU 5001 not only handles loading contexts 5003 for SPU processing, but also manages a queuing system for uploading packets into memory from input and downloading packets from memory to output after processing. As may be logically inferred, there are several regimens and characteristics concerning packet order and flow that must be observed and followed by PMU 5001 for successful functioning. It is the integrity of these regimens and characteristics that must be tested and validated before reliable field operation can be assumed. More detail regarding PMU characteristics concerned with packet order and flow is provided below.

FIG. 51 is a diagram of desired ordering of packet flows concerning ingress and egress managed by PMU 5001 of FIG. 50 according to an embodiment of the present invention. PMU 5001, in this example, is logically illustrated in ongoing process of uploading packets for processing and downloading packets to output after SPU processing. SPU 5002 and SIU 5000 are logically illustrated together as one block retaining both element numbers introduced with reference to FIG. 50. A bi-directional arrow illustrated between PMU 5001 and SPU, SIU (5002, 5000) represents communication between the components.

A table is illustrated at lower left of FIG. 51 and identifies 3 separate and unrelated flows of data packets. These are Flow A, Flow B, and Flow C, as so labeled. In actual practice, a PMU can be configured to handle more than 3 packet flows simultaneously, however 3 are shown here and deemed sufficient for descriptive purpose. An incoming packet stream 5102 labeled “Packets In” represents an inflow of packets, including packets belonging to each of the exemplary three flows.

Within each packet flow A, B, and C, individual packets are numbered generally from 0 to 3 within incoming stream 5102 in a specific order. For example, packet flow A contains packets 0, 1, 2, and 3. Packet flow B contains packets 0 and 1. Packet flow C contains packets 0, 1, and 2. It will be appreciated that packets from different flows may be received randomly at PMU 5001, and that the order in which the packets arrive is, and must be, considered as the correct order.

Data packet flows A, B, and C are typically independent from each other, however data packets within a same flow, A for example, typically exhibit certain dependencies. It is a functional requirement of PMU 5001 to ensure that the order of packets arriving as part of a particular flow is maintained when the packets of the flow are sent out. That is, the router of which the PMU is a part, should not send the packets for a flow out in a different order than they were received. Software running in the SPU can obfuscate any particular ordering of data packets output from the system, however, in the absence of software intervention, PMU 5001 should maintain the received order of packets with respect to their association to a particular packet flow at output.

It is noted herein in this example, that flow and packet order will be read and identified from left to right regarding illustrated streams. This is simply to avoid confusion as adapting to actual physical stream characteristics in terms of direction “into” and “out of” PMU 5001 as illustrated by directional arrows would cause indication that 3 is a first packet and 0 is a fourth packet of flow A in stream 5102 for example. It will logically be presumed that the stated order will be from left to right wherein packet 0 of flow A is the first packet of stream 5102 to be received, and packet 3 is the fourth, and so on for the other flows.

PMU 5001 is capable of, and not constrained from, sending packets out in a different flow ordering than received as long as the packets within each individual flow are serially sent out in the same order sequence as they arrived. For example, 3 output data streams 5103 are illustrated to the right of PMU 5001. The 3 streams 5103 are labeled Packets Out and qualified as 3 possible valid orderings of an output stream.

A specific ordering illustrated as the first of 3 alternate streams exhibits an exact ordering to that of incoming stream 5102 with respect to packet order within the 3 packet flows and with respect to the ordering of packets at large regardless of flow assignment. This stream, of course, may be assumed to be valid under flow-ordering rules. The remaining stream examples exhibit differences in flow order but maintain serial order of packets within each represented flow. For example, the second (middle) stream example of the three in 5103 starts with packet 0 from flow C, packet 0 from flow B, and packet 0 from flow A whereas the order of the first three packets of incoming stream 5102 is packet 0 from flow A, packet 1 from flow A, and packet 0 from flow B. These just-described orders are also valid because the individual packet order within each represented flow is maintained at output by PMU 5001.

All three output streams 5103 are correct and valid outputs from a point of view of high-level functionality. The absolute correct output depends highly on the specifics of micro-architecture of the PMU implementation and on software code that runs on the SPU processing core.

The example of FIG. 51 illustrates just one of the characteristics of packet output activity accomplished by PMU 5001. However, there are several characteristics to consider when qualifying output activity by PMU 5001. These characteristics are:

-   -   Packet order: software can decide to send packets within the         same flow in a different order in spite of PMU constraints.     -   Packet drop: either software or hardware (PMU) can drop certain         data packets packets. These dropped packets will not be sent         out.     -   Packet insertion: software can create packets and send them out.         In this case, these packets did not arrive to PMU from the         network.     -   Packet modification: as a result of the processing, the content         of a data packet can be modified. A particular case is when the         size (tail, header, or both) of the packet is increased or         decreased as a result of processing.

The variables listed just above need to be considered when building a functional PMU validation environment. Moreover, for a particular test run, a test code assigned thereto will enable or disable in terms of test workload any single or combination set of the 4 above-described variables. More detail about configuration parameters is presented later in this specification.

FIG. 52 is a block diagram of a PMU validation environment according to an embodiment of the present invention. A hardware/software environment for PMU validation comprises, most importantly, a working model of PMU/SPU/SIU interactive function. This aspect is represented in the environment of this example by a machine 5204 labeled Model. Although this model is represented in FIG. 2 by a server icon, it may be made in any of several different ways. It may be, as described briefly above, a single chip, a software simulation running on a computer, or a combination of both. SIU and SPU function can either be actual hardware implementations or simulated by software in terms of interoperability and interface capability to the PMU. The PMU portion of model 5204, likewise, can be software simulated or an actual unit. A block illustrating PMU/SPU/SIU interaction is illustrated as associated with model 5204 by a dotted line for purpose of clarity only. Model in FIG. 52 is meant to represent that which is to be validated.

A test generator 5203 is provided for the purpose of generating test packets for input into model 5204 according to provided parameters for specific tests. A user interface 5201 and labeled User Input is provided and adapted to enable a user to configure tests by entering test parameters and special test validation codes into generator 5203. Interface 5201 is represented in this example by a computer icon. Arrows labeled Test Parameters and Test Code are illustrated as output from interface 5201 into Test Generator 5203.

A test run checker 5205 is provided and adapted to receive packets output from test model 5204 and to receive a copy of applicable test code from user interface 5201 at the time of, during, or before of a particular test run by a user. Checker 5205 in one embodiment is implemented as a processor for evaluating results and comparing them against test criteria. Results from processing of checker 5205 may be assumed to be displayable on a display of user interface 5201. The primary result produced by checker 5205 in the processing of output activity during a test is either pass or fail. A primary function of the Checker is t compare the actual packet output from the model with expected output for a properly-functioning machine.

In practice, a user enters specific parameters and a test codes into generator 5203 and copies the test code to the checking processor (5205) for use in comparative analysis. If a run succeeds, it means the PMU has met all of the requirements. If a test run fails, the PMU has not provided the correct output, and checker 5205 has ability to notify a user as to probable or exact cause of failure.

As described above, a user operating interface 5201 specifies a list of test parameters related to a pending test. These parameters specify the limits of the values to be generated for each of the possible variables of the test. A test code is assigned equating to the information of the output packet activity characteristics expected. The test code is represented per test run by machine or human readable assigned values. One value is equated to a specific possible variable, which would combine enable, or disable states of the 4 variables of packet modification, packet insertion, packet drop, and packet order.

A test is generated using an automated test generator tool 5203, which is illustrated as a separate computing machine in FIG. 52, but might well be software executing on a single machine with interface 5201. A single test input comprises a sequence of input data packets and a workload parameter associated to each packet. Model 5204 generates an output packet stream in response, and the output stream is evaluated. The output packet activity is examined using automated test checker tool 5205. Checker 5205, using the assigned test code to access a rule set, determines whether the output packet activity is valid and, if so, it will notify that the PMU Passed. Otherwise, checker 5205 will notify that the PMU Failed. In a preferred embodiment, in the event of test failure, checker 5205 may also provide a detailed summary of why the particular test failed.

An assigned test code can be embedded in a convenient portion of each data packet to be streamed into model 5204, or it may be provided to model 5204 through a separate and dedicated interface. It is important to note that the actual or exact data format and characteristics of the test code are not essential to the practice of the present invention as long as it is machine-readable and can be associated per packet sequence for evaluation purpose.

FIG. 53 is a flow diagram illustrating steps for conducting a PMU validation process according to an embodiment of the present invention. At step 5300, the user specifies and inputs a list of test parameters (range of values) related to a specific test run into a test generator analogous to generator 5203 of FIG. 52. The user may use a computer such as that represented as interface 5201 of FIG. 52. In this step, the user also assigns a test code to be used for evaluation purpose.

The PMU under validation will receive four types of activity from the SPU and/or SIU. For example, packet input activity to the PMU from the SIU portion of model 5204. A packet input from the SIU model contains all of the packet data.

Memory request activity also comes to the PMU from the SIU whether it is actually sourced from the PMU itself or from the SPU. This input activity comprises all of the reads and writes that the SIU performs to memory, specifically local packet memory (LPM) under control of the PMU. These requests can be generated by the PMU itself (when pre-loading a context with some bytes of the packet) or by the SPU (when executing a load or store instruction that accesses the local packet memory).

Configuration register request activity also comes to the PMU by way of the SIU. This activity corresponds to the reads and writes to configuration space within the PMU. These accesses are initiated by the SPU through load and store operations. The SIU interfaces these accesses and the SIU will actually interact with the PMU. This activity shares the same interface as the memory request activity.

Packet instruction activity is generated in the SPU and sent to the PMU. Packet instruction activity equates to all of the different instructions executed by the PMU as a result of SPU dispatch from one or more processing streams. Instructions are cached at the PMU on a FIFO basis. All 4 of these activities must be represented in testing.

At step 5301 a test is generated using the test generator referred to with respect to FIG. 52 above as generator 5203. At step 5303, the generated test packets are streamed into model 5204. At step 5304, the model generates an output packet stream. At step 5305 the output stream is examined using a processing tool analogous to the described checker tool 5205 of FIG. 52. If in step 5305 the checker determines that the test run is a success based on activity and code consultation, notification is then sent at step 5307 that the test passed.

If however in step 5305, the test failed, then a failure notice would be sent at step 5308, in a preferred instance listing the exact cause or causes for the failure. The ability to specify all possible results using test code enables troubleshooting causes of failure in simulation.

It will be apparent to one with skill in the art that the process described by steps 5300-5308 may be modified by adding sub-steps without departing from the spirit and scope of the present invention. The inventor intends that the process steps illustrated in this example represent just one basic test sequence.

FIG. 54 is a table illustrating test code assignments according to an embodiment of the present invention. As was previously described, test codes are generated for the purpose of evaluating packet output activity according to code criteria. A table 5400 represents test code assigned values for variations of possible activity characteristics. In this example there are 16 test codes (0-15) covering 16 distinctly different combinations.

A column 5401 is illustrated within table 5400 and is labeled Packet Modification. A column 5402 is illustrated as a next column within table 5400 and labeled Packet Insertion. A column 5403 is illustrated within table 5400 and labeled Packet Drop. A column 5404 is illustrated within table 5400 and labeled Packet order. A final column 5405 represented within table 5400 is labeled Test Code.

Sixteen rows containing values are arranged under the described column headings. Each row reflects a different mix of output packet activity that may be observed during a test. Table 5400 is analogous to a logic truth table covering 16 possible scenarios representing different combinations of the 4 listed characteristics described with reference to FIG. 51 above.

In this example, a first row has a value of no (constraint) listed for packet modification, a value of no listed for packet insertion, a value of no listed for packet drop, and a value of no listed for packet order. The assigned test code for this row of criteria for a given test is 0. Therefore, selecting a test code of 0 for a particular run means that in order to pass, there can be no packet modification of test packets; there can be no packets dropped; and software cannot change the packet order within a flow.

The following row represents the same criteria except that software is allowed to change packet order within a flow. Therefore the assigned code is 1 for this set of criteria. The criteria for code 10 in table 5400 is as follows: Packets in this run can be modified; Packets may not be inserted that were not part of the original test stream; Packets may be dropped; and software may not re-order packet sequence within a flow.

In addition to the criteria covered by a test code, the numerous values that shape activity at each of the PMU interfaces must have coverage whereby by a user configuring a test must set range parameters. These many parameters include, but are not limited to

Packet input:

Number of total packets:

Arrival time of packets:

Number of different packet flows:

Number of packets per flow:

Packet size:

Packet contents:

Memory request:

Memory reads (address):

Memory writes (address+data):

Configuration register request:

Configuration register reads (configuration register number):

Configuration register writes (configuration register number+data):

Packet instructions:

Number of instructions per packet:

Arguments for the different instructions:

Packet Number:

Register Number:

Physical Address:

Packet Page:

Queue Number:

Delta:

Device Id:

Keep Space:

Context Number:

Mask Number:

And so on.

It is the task of the configuring user to specify the ranges of values that the generator will use when generating actual values for each of the above-listed variables involved in a test. The user also specifies the characteristics of the packet output activity by specifying the test code for a run from the assigned codes listed in table 5400.

The workload associated with packet processing is defined as a list of packet instructions and memory and configuration register accesses that the processing core (SPU) would execute upon the activation of a packet of an input test stream into one of the available contexts.

The generation of a workload is shaped using both user input ranges of variables and a selected test code value. Depending on the test code value, some of the workload and memory/configuration register accesses will not be allowed to be part of the test because otherwise it will violate the characteristics that the user explicitly specified and explicitly prohibited when specifying the test code. The workload can be generated in a random fashion or directed through user directions. In any case, the restrictions placed by selecting a specific test code will be enforced.

Other commands applicable to a test are packet independent, meaning that they may affect all of the inserted packets. These commands include, but are not limited to, further configuration register reads and writes; the rate at which the input packet data is sent to the test model; commands associated with an on-chip instrumentation interface, commands associated with a performance counter interface, and commands relating to workload to be executed at boot time by a particular context(s).

Further to the method of testing, a generated test is converted into a required sequence of input vectors and these vectors are fed into a model analogous to model 5204 of FIG. 52. Out of the input vectors associated with all of the components, eventually the PMU-specific input vectors will be input to the PMU model under functional validation.

For each different packet of an input stream that is generated and input into the model environment, an identifier is created in association thereof and sent also into the model environment. There are two ways to send packet identifiers into the model environment. It can be inserted into a convenient location in an associated data packet, or communicated separately to the model environment over a dedicated and separate interface.

The identifier of a packet contains a flow identification value to which the packet belongs, and a sequence number of the packet within that flow. If specified workload is such that packets not generic to the original test input may be generated and inserted during a test by software, a well determined packet identifier will be associated to that packet in order to enable identification in output activity.

The generator that will generate the input activity to the test model needs to know which method of the above-described methods packet identifiers are input to the model. This is because it is packet identifiers that are used to locate, in the test itself, workload associated to an identified packet that needs to be executed.

The PMU portion of the model generates output activity as a result of the input vectors. This output activity is captured by the validation environment (checker) and used to determine whether the PMU model has successfully processed the packets specified in the test according to the criteria of the test code.

A particular test is run for a specific number of cycles, or until the test finishes. There are alternative methods for detecting when a test run has finished. One method is by counting the total number of data packets in the output activity. The counted number should equal a total number of packets input into the model plus any packets inserted by software during the test minus any packet dropped by software during the test. However, if a packet is dropped by hardware in this case there is a notification thereof sent to the validation environment (checker).

Another method is by generating a very low priority packet (sweep packet) that is sent into the model after all the input test packets have been sent. This packet is processed last, and sent out of the model last. A special packet identifier is assigned to this packet. Therefore, as soon as this sweep packet is sent out, the validation environment detects it and finishes the test. This method is the one currently implemented in the PMU validation environment in a preferred embodiment.

To validate or invalidate a particular test run, the checker (5205), which is a software implementation, perhaps running on a separate processor, will receive output activity generated by the model (5204) and it will examine whether the four different characteristics of the output activity are met. The checker uses the assigned test code generated by the user interface program to know which of the 4 characteristics are set and which are not. For those set to yes, the output activity may or may not exhibit the characteristic. For those characteristics set to no, the output activity should not present the characteristic. For example, if the test code is 10, packet drops might have occurred but no packet insertion by software should have occurred. To check for packet modification, the checker needs to have the information of the contents of the packets that were part of the test.

Determination of a test failure is, in a preferred embodiment, augmented with the appropriate packet identifiers of the data packets that caused the failure. Using the identifier, the checker program can pull the generation data and the actual packet data to report the cause of failure, provided that suitable structures are provided for storing the data.

It is noted herein that in lieu of automated testing, which is described in this specification, a user may also write his or her own directed test wherein the test results (output activity) are examined manually by a user to determine pass or failure of the test. In this case, the test generator and the test checker are not required.

The method and apparatus of the present invention may be practiced on a combination of hardware and software models. The software test code for treating the possible combinations of output characteristics can be implemented singularly for a test run, that is to say that one code is used at a time, or the code may be staged and sequenced for automated repeat runs of a same test stream wherein each run uses a different code. The method and apparatus is applicable to testing and validation of a data processing environment wherein packet-processing responsibilities of a data router are shared to separate components, a software processing application and a hardware processor implemented at input/egress circuitry. While the validation model taught herein is, in practice, specific to data packet routers utilizing DMS technology, it is clear that versions of the model can be applied to validating other types of processing environments. Accordingly the claims that follow should be accorded the broadest interpretation. 

1-25. (canceled)
 26. A validation system for validating functions of a packet management unit (PMU) operationally coupled through a system interface to a stream processing unit of a packet processor, the validation system comprising: a model configured to emulate functions of the PMU, the system interface, and the stream processing unit; and evaluation software for checking results; wherein the model is further configured to: receive an input packet stream; process the input packet stream; and generate output activity; and wherein the evaluation software is configured to compare the output activity to criteria of a test code resulting in an indication of pass or failure.
 27. The validation system of claim 26, further comprising a test generator coupled to the model, wherein the test generator is configured to: receive the test code; and convey input packet activity to the model in the form of a packet stream corresponding to the test code.
 28. The validation system of claim 26, wherein the system interface and the stream processing unit of the model are simulated in software running on a processor-based machine.
 29. The validation system of claim 28, wherein the PMU is simulated in software running on a processor-based machine.
 30. The validation system of claim 26, wherein the model emulates integrated functions of a data packet router.
 31. The validation system of claim 26, wherein the input packet stream includes at least one associated workload, the workload specifying one or more parameters of a group of parameters comprising: packet input parameters; memory request parameters; PMU configuration parameters; and packet instructions.
 32. The validation system of claim 26, wherein each packet of the input packet stream includes an associated workload, the workload specifying one or more parameters of a group of parameters comprising: packet input parameters; memory request parameters; PMU configuration parameters; and packet instructions.
 33. The validation system of claim 26, wherein the test code comprises a plurality of values representing different combinations of possible test variables associated with treating data packets in process; and wherein the test variables include the possibility of packet modification by software, packet insertion by software, packet dropping by hardware or software, and packet reordering by software.
 34. The validation system of claim 26, wherein each packet of the input packet stream includes a test code.
 35. The validation system of claim 26, wherein the input packet stream includes a plurality of packet flows, each packet flow comprising a plurality of packets; and wherein the model is configured to output packets of a given flow in an order that matches an order in which packets of the given flow were received.
 36. A validation system comprising: a model configured to: emulate a packet processor including a packet management unit (PMU) coupled through a system interface to a stream processing unit; and generate an output packet stream in response to receiving an input packet stream; and a checker coupled to the model, wherein said checker is configured to: receive a test code including criteria for evaluating an output packet stream; receive a test output packet stream generated by the model; and compare the test output packet stream to the criteria to determine success or failure of a test of the model.
 37. The validation system of claim 36, wherein the test code comprises a plurality of values representing different combinations of possible test variables associated with processing packets; and wherein processing steps enabled or disabled by the test variables include packet modification by software, packet insertion by software, packet dropping by hardware or software, and packet reordering by software.
 38. The validation system of claim 36, wherein the input packet stream includes at least one associated workload, the workload specifying one or more parameters of a group of parameters used by the model comprising: packet input parameters; memory request parameters; PMU configuration parameters; and packet instructions.
 39. A method for validating functions of a packet-management unit (PMU) operationally coupled through a system interface to a stream processing unit of a packet processor, the method comprising: emulating functions of the PMU, the system interface, and the stream processing unit in a model; inputting a packet stream into the model; outputting from the model an output activity representing the packet stream after processing; and examining the output activity according to input parameters and criteria of a test code to determine if a concluded test has passed or failed.
 40. The method of claim 39, further comprising a test generator: receiving the test code; and conveying input packet activity to the model in the form of a packet stream corresponding to the test code.
 41. The method of claim 39, wherein said emulating further comprises simulating the system interface and the stream processing unit in software running on a processor-based machine.
 42. The method of claim 41, wherein said emulating further comprises simulating the PMU in software running on a processor-based machine.
 43. The method of claim 39, wherein said emulating further comprises emulating integrated functions of a data packet router.
 44. The method of claim 39, wherein the packet stream includes at least one associated workload, the workload specifying one or more parameters of a group of parameters comprising: packet input parameters; memory request parameters; PMU configuration parameters; and packet instructions.
 45. The method of claim 39, wherein each packet of the packet stream includes an associated workload, the workload specifying one or more parameters of a group of parameters comprising: packet input parameters; memory request parameters; PMU configuration parameters; and packet instructions.
 46. The method of claim 39, wherein the test code comprises a plurality of values representing different combinations of possible test variables associated with treating data packets in process; and wherein the test variables include the possibility of packet modification by software, packet insertion by software, packet dropping by hardware or software, and packet reordering by software.
 47. The method of claim 39, wherein the packet stream includes a plurality of packet flows, each packet flow comprising a plurality of packets, the method further comprising outputting from the model packets of a given flow in an order that matches an order in which packets of the given flow were received.
 48. A method of validating functions of a packet-management unit (PMU), the method comprising: emulating in a model, a packet processor including a packet management unit (PMU) coupled through a system interface to a stream processing unit; the model generating an output packet stream in response to receiving an input packet stream; receiving a test code including criteria for evaluating an output packet stream; receiving a test output packet stream generated by the model; and comparing the test output packet stream to the criteria to determine success or failure of a test of the model.
 49. The method of claim 48, wherein the test code comprises a plurality of values representing different combinations of possible test variables associated with processing packets; and wherein processing steps enabled or disabled by the test variables include packet modification by software, packet insertion by software, packet dropping by hardware or software, and packet reordering by software.
 50. The method of claim 48, wherein the input packet stream includes at least one associated workload, the workload specifying one or more parameters of a group of parameters used by the model comprising: packet input parameters; memory request parameters; PMU configuration parameters; and packet instructions.
 51. A computer readable medium containing instructions that, when executed, enable a processor to validate functions of a packet-management unit (PMU) operationally coupled through a system interface to a stream processing unit of a packet processor by: emulating functions of the PMU, the system interface, and the stream processing unit in a model; inputting a packet stream into the model; outputting from the model an output activity representing the packet stream after processing; and examining the output activity according to input parameters and criteria of a test code to determine if a concluded test has passed or failed.
 52. The computer readable medium of claim 51, containing further instructions that, when executed, enable a processor to implement a test generator configured to: receive the test code; and convey input packet activity to the model in the form of a packet stream corresponding to the test code.
 53. The computer readable medium of claim 51, wherein said emulating further comprises simulating the system interface and the stream processing unit in software running on a processor-based machine.
 54. The computer readable medium of claim 53, wherein said emulating further comprises simulating the PMU in software running on a processor-based machine.
 55. The computer readable medium of claim 51, wherein said emulating further comprises emulating integrated functions of a data packet router.
 56. The computer readable medium of claim 51, wherein the packet stream includes at least one associated workload, the workload specifying one or more parameters of a group of parameters comprising: packet input parameters; memory request parameters; PMU configuration parameters; and packet instructions.
 57. The computer readable medium of claim 51, wherein each packet of the packet stream includes an associated workload, the workload specifying one or more parameters of a group of parameters comprising: packet input parameters; memory request parameters; PMU configuration parameters; and packet instructions.
 58. The computer readable medium of claim 51, wherein the test code comprises a plurality of values representing different combinations of possible test variables associated with treating data packets in process; and wherein the test variables include the possibility of packet modification by software, packet insertion by software, packet dropping by hardware or software, and packet reordering by software.
 59. The computer readable medium of claim 51, wherein the packet stream includes a plurality of packet flows, each packet flow comprising a plurality of packets; and wherein the computer readable medium contains further instructions that, when executed, enable the processor to output from the model packets of a given flow in an order that matches an order in which packets of the given flow were received.
 60. A computer readable medium containing instructions that, when executed, enable a processor to validate functions of a packet-management unit (PMU) by: emulating in a model, a packet processor including a packet management unit (PMU) coupled through a system interface to a stream processing unit; the model generating an output packet stream in response to receiving an input packet stream; receiving a test code including criteria for evaluating an output packet stream; receiving a test output packet stream generated by the model; and comparing the test output packet stream to the criteria to determine success or failure of a test of the model.
 61. The computer readable medium of claim 60, wherein the test code comprises a plurality of values representing different combinations of possible test variables associated with processing packets; and wherein processing steps enabled or disabled by the test variables include packet modification by software, packet insertion by software, packet dropping by hardware or software, and packet reordering by software.
 62. The computer readable medium of claim 60, wherein the input packet stream includes at least one associated workload, the workload specifying one or more parameters of a group of parameters used by the model comprising: packet input parameters; memory request parameters; PMU configuration parameters; and packet instructions. 